CN115771677A - Composite material processing is with preventing solidification buffer memory jar - Google Patents

Abstract

The invention discloses an anti-curing cache tank for composite material processing, which comprises two main shafts, wherein the two main shafts are horizontal and parallel, a first U-shaped frame is rotatably arranged at the end part of each main shaft, a connecting arm is fixed on the first U-shaped frame, and a second U-shaped frame is fixed at the outer end of the connecting arm; through making the jar body be in the state of rolling to it all is multi-direction alternating swing state in horizontal direction and vertical direction, can conveniently make the internal material of jar be in multi-direction alternating flow state all the time, thereby conveniently make the material of the internal different degree of depth of jar, different positions continuously exchange, improve the flow comprehensiveness of material, avoid the long-time static solidification of material or the layering phenomenon appears, guarantee the fluidility and the homogeneity of material, thereby conveniently prepare for follow-up material processing.

Description

Composite material processing is with preventing solidification buffer memory jar

Technical Field

The invention relates to the technical field of new material processing in emerging industries, in particular to an anti-curing cache tank for composite material processing.

Background

The composite material is also called a high-performance composite material, is a new material formed by optimally combining material components with different properties by using an advanced material preparation technology, has the advantages of chemical stability, friction reduction, wear resistance, self lubrication, heat resistance, fatigue resistance, creep resistance, noise elimination, electric insulation and the like, and is widely applied to the fields of various machines, chemical engineering, daily necessities and the like.

Composite material generally need save in the buffer memory jar after compounding processing and keep in to the convenience is prepared for subsequent processing, and traditional buffer memory jar is a simple jar of body, and when the material was stored in this buffer memory jar, the material generally is static, and because the material is stood for a long time, it solidifies or takes place the layering phenomenon in the buffer memory jar easily, leads to the unable normal use of material.

Disclosure of Invention

In order to solve the technical problem, the invention provides an anti-curing cache tank for processing a composite material.

In order to achieve the purpose, the invention adopts the technical scheme that:

an anti-solidification buffer tank for composite material processing comprises two main shafts, wherein the two main shafts are horizontal and parallel, a first U-shaped frame is rotatably arranged at the end part of each main shaft, a connecting arm is fixed on the first U-shaped frame, a second U-shaped frame is fixed at the outer end of the connecting arm, a tank body is arranged between the two second U-shaped frames, and the tank body is rotatably connected with the second U-shaped frames;

and the rotating axis of the tank body on the second U-shaped frame is vertical to the rotating axis of the first U-shaped frame on the main shaft.

The connecting shaft is rotatably connected with the circular groove plate, and a torsion spring is connected between the connecting shaft and the circular groove plate;

wherein, the diameter of the circular groove plate is equal to the diameter of the main shaft.

Furthermore, a motor is fixed on the side wall of the vertical plate, a first straight gear is arranged at the output end of the motor, a second straight gear is arranged on the first straight gear in a meshed mode, a transmission shaft is arranged on the second straight gear, the transmission shaft is rotatably installed on the vertical plate, bevel gears are arranged at the two ends of the transmission shaft, bevel gear rings are arranged on the bevel gears in a meshed mode, one bevel gear ring is fixed on the main shaft, and the other bevel gear ring is fixed on the circular groove plate.

Furthermore, a plurality of through holes are formed in the middle of the outer wall of the tank body and are distributed in an annular shape, a rotating ring is rotatably sleeved in the middle of the outer wall of the tank body and blocks the through holes, a feed valve and a discharge valve are arranged on the outer wall of the rotating ring, a discharge pipe is communicated with the discharge valve, a support rod is fixed on the side wall of the vertical plate, and the outer end of the support rod is connected with the discharge pipe;

wherein, be provided with guide structure on the riser lateral wall, guide structure is used for carrying out spacing direction to the rotating ring, makes rotating ring and jar body relative rotation.

Furthermore, the guide structure comprises a connecting ball which is rotatably embedded on the outer wall of the rotating ring, a telescopic rod is fixed on the outer wall of the connecting ball, the telescopic rod is perpendicular to the vertical plate, and a first plate spring is connected between the fixed end and the movable end of the telescopic rod;

the side wall of the vertical plate is transversely provided with a first guide rail, the first guide rail is vertically provided with a second guide rail, the second guide rail slides on the first guide rail, the second guide rail is provided with a sliding block in a sliding manner, and the sliding block is connected with the fixed end of the telescopic rod.

Furthermore, a sliding sleeve is arranged on the outer wall of the main shaft in a sliding mode, two right-angle top plates are arranged on the outer wall of the sliding sleeve relatively, a connecting line between the two right-angle top plates is perpendicular to the direction of the rotating axis of the first U-shaped frame on the main shaft, and a second plate spring is connected between the sliding sleeve and the main shaft.

Furthermore, a plurality of sliding edges are fixed on the outer wall of the main shaft, the sliding edges penetrate through the sliding sleeve, the sliding sleeve slides on the sliding edges, the outer side of the sliding sleeve is provided with an arched limiting plate in a spanning mode, and the arched limiting plate is fixed on the outer wall of the main shaft.

Furthermore, an outer cover is arranged on the side wall of the vertical plate and is positioned on the outer side of the circular groove plate, the motor, the first straight gear, the second straight gear, the transmission shaft, the bevel gear and the bevel gear ring.

Compared with the prior art, the invention has the beneficial effects that: through making the jar body be in the state of rolling to it all is multi-direction alternating swing state in horizontal direction and vertical direction, can conveniently make the internal material of jar be in multi-direction alternating flow state all the time, thereby conveniently make the material of the internal different degree of depth of jar, different positions continuously exchange, improve the flow comprehensiveness of material, avoid the long-time static solidification of material or the layering phenomenon appears, guarantee the fluidility and the homogeneity of material, thereby conveniently prepare for follow-up material processing.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments described in the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a rear view of the vertical plate in FIG. 1;

FIG. 3 is a schematic view of the internal structure of the housing of FIG. 2;

FIG. 4 is a schematic sectional view of the circular groove plate of FIG. 3;

FIG. 5 is an enlarged schematic view of the principal axis of FIG. 1;

FIG. 6 is a schematic view of the tank of FIG. 1 in a cross-sectional enlarged configuration;

FIG. 7 is an enlarged schematic view of the guide structure of FIG. 1;

in the drawings, the reference numbers: 1. a main shaft; 2. a first U-shaped frame; 3. a connecting arm; 4. a second U-shaped frame; 5. a tank body; 6. a vertical plate; 7. a connecting shaft; 8. a circular groove plate; 9. a torsion spring; 10. a motor; 11. a first straight gear; 12. a second spur gear; 13. a drive shaft; 14. a bevel gear; 15. a conical gear ring; 16. a port; 17. a rotating ring; 18. a feed valve; 19. a discharge valve; 20. a discharge pipe; 21. a support bar; 22. a connecting ball; 23. a telescopic rod; 24. a first plate spring; 25. a first guide rail; 26. a second guide rail; 27. a slider; 28. a sliding sleeve; 29. a right angle top plate; 30. a second plate spring; 31. edge smoothing; 32. an arched limiting plate; 33. a housing.

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.

In the description of the present invention, it should be noted that the orientations or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like are based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; either directly or indirectly through intervening media, or may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art. This embodiment is written in a progressive manner.

As shown in fig. 1 to 5, the solidification prevention buffer tank for processing composite materials comprises two main shafts 1, wherein the two main shafts 1 are horizontal, the two main shafts 1 are parallel, a first U-shaped frame 2 is rotatably arranged at the end part of each main shaft 1, a connecting arm 3 is fixed on each first U-shaped frame 2, a second U-shaped frame 4 is fixed at the outer end of each connecting arm 3, a tank body 5 is arranged between the two second U-shaped frames 4, and the tank body 5 is rotatably connected with the second U-shaped frames 4;

the rotation axis of the tank 5 on the second U-shaped frame 4 is vertical to the rotation axis of the first U-shaped frame 2 on the main shaft 1.

Specifically, the tank 5 is used for storing materials, when the axis of the tank 5 is parallel to a vertical surface, the first U-shaped frame 2 and the spindle 1 are in a mutually inclined state, and an included angle between the first U-shaped frame 2 and the spindle 1 is an obtuse angle, one spindle 1 is rotated, the spindle 1 stirs the tank 5 to rotate through the first U-shaped frame 2, the connecting arm 3 and the second U-shaped frame 4, the tank 5 can drive the first U-shaped frame 2, the connecting arm 3 and the second U-shaped frame 4 on the other spindle 1 to synchronously rotate, so as to drive the other spindle 1 to synchronously rotate, because the rotation axis of the tank 5 on the second U-shaped frame 4 is perpendicular to the rotation axis of the first U-shaped frame 2 on the spindle 1, when the two spindles 1 rotate, the rotation track of the tank 5 is gourd-shaped, that projections of the end of the tank 5 in the transverse direction and the longitudinal direction are both annular motion tracks, and the tank 5 is in the continuous turning state in the whole motion process, the projections of the two ends of the vertical surface are in a staggered swing state, the tank 5 can drive the materials in the tank 5 to continuously in the rolling state and the multi-direction swing motion, so that the materials in the tank 5 can alternately flow in multiple directions can be solidified or solidified in a layered manner.

Through making jar body 5 be in the state of rolling to it all is multi-direction alternating swing state in horizontal direction and vertical direction, can conveniently make the material in jar body 5 be in multi-direction alternating flow state all the time, thereby conveniently make the material of the different degree of depth, different positions in jar body 5 continuously exchange, improve the flow comprehensiveness of material, avoid the long-time static solidification of material or the layering phenomenon appears, guarantee the fluidility and the homogeneity of material, thereby conveniently prepare for follow-up material processing.

As shown in fig. 3 to 4, as a preferable embodiment, the vertical plate 6 is further included, the two main shafts 1 penetrate through the vertical plate 6, the main shafts 1 are rotatably connected with the vertical plate 6, a connecting shaft 7 is fixed at an end of one vertical plate 6, a circular groove plate 8 is buckled on an outer side of the connecting shaft 7, the connecting shaft 7 is rotatably connected with the circular groove plate 8, and a torsion spring 9 is connected between the connecting shaft 7 and the circular groove plate 8;

wherein the diameter of the circular slotted plate 8 is equal to the diameter of the main shaft 1.

Specifically, the torsion spring 9 is in an elastic deformation state and generates elastic tension on the connecting shaft 7 and the circular groove plate 8, the circular groove plate 8 and the main shaft 1 without the circular groove plate 8 are synchronously rotated, the main shaft 1 can directly drive the tank body 5 and the main shaft 1 with the circular groove plate 8 installed thereon to rotate, and meanwhile, as the circular groove plate 8 rotates and the torsion spring 9 is in an elastic deformation state, the circular groove plate 8 can provide elastic rotation thrust for the main shaft 1 through the torsion spring 9 and the connecting shaft 7, so that rotation power is synchronously provided for the two main shafts 1.

In the time of in-service use, because two main shafts 1 rotate the time of a week the same, and two main shafts 1 in this a week are in the differential motion state all the time to need to make one main shaft 1 as the driving shaft, and another main shaft 1 is as the driven shaft, through adopting the structure of connecting axle 7, circular frid 8 and torsional spring 9, can conveniently provide power supply for two main shafts 1 are synchronous, and can satisfy the work demand of two main shafts 1 differential motion.

Through the diameter that makes circular frid 8 the same with main shaft 1's diameter, can conveniently make circular frid 8 and the main shaft 1 who does not install circular frid 8 keep with fast synchronous rotation, thereby the convenience is according to week pivoted in-process at two main shafts 1, the elastic variation of torsional spring 9 is reciprocating type change state, avoid circular frid 8 and the main shaft 1 who does not install circular frid 8 differential rotation to appear and lead to torsional spring 9 to be and last one-way deformation state, avoid torsional spring 9 to take place to warp and damage, guaranteed that torsional spring 9 is in reciprocating type deformation state all the time in its allowed band.

As shown in fig. 3, as a preferred embodiment, a motor 10 is fixed on a side wall of the vertical plate 6, an output end of the motor 10 is provided with a first straight gear 11, a second straight gear 12 is arranged on the first straight gear 11 in a meshing manner, a transmission shaft 13 is arranged on the second straight gear 12, the transmission shaft 13 is rotatably mounted on the vertical plate 6, both ends of the transmission shaft 13 are provided with bevel gears 14, the bevel gears 14 are provided with bevel gear rings 15 in a meshing manner, one of the bevel gear rings 15 is fixed on the main shaft 1, and the other bevel gear ring 15 is fixed on the circular groove plate 8.

Specifically, the motor 10 drives the transmission shaft 13 to rotate through the first straight gear 11 and the second straight gear 12, and the transmission shaft 13 drives the main shaft 1 and the circular fluted plate 8 to synchronously rotate at the same speed through the bevel gear 14 and the bevel gear ring 15, so as to drive the equipment to operate.

As shown in fig. 6, as a preferred embodiment of the present invention, a plurality of through openings 16 are formed in the middle of the outer wall of the tank 5, the plurality of through openings 16 are distributed in an annular shape, a rotating ring 17 is rotatably sleeved in the middle of the outer wall of the tank 5, the rotating ring 17 blocks the through openings 16, a feed valve 18 and a discharge valve 19 are arranged on the outer wall of the rotating ring 17, a discharge pipe 20 is arranged on the discharge valve 19 in a communicating manner, a support rod 21 is fixed on the side wall of the vertical plate 6, and the outer end of the support rod 21 is connected to the discharge pipe 20;

wherein, be provided with guide structure on the riser 6 lateral wall, guide structure is used for carrying out spacing direction to swivel 17, makes swivel 17 and jar body 5 relative rotation.

Specifically, the rotating ring 17 can be rotated on the tank body 5 through the guiding structure, the rotating ring 17 cannot perform turnover movement, the feeding valve 18 is located on the upper side of the rotating ring 17, the discharging valve 19 is located on the lower side of the rotating ring 17, when the material is required to be guided into the tank body 5, the axis of the tank body 5 is turned to be in a horizontal state, at the moment, the external material can be guided into the tank body 5 through the feeding valve 18 and the through hole 16, when the material in the tank body 5 is required to be discharged, the horizontal state is realized when the axis of the tank body 5 is turned, the material in the tank body 5 can be guided out through the through hole 16, the discharging valve 19 and the discharging pipe 20, by adopting the structure of the through hole 16 and the rotating ring 17, the directions of the feeding valve 18 and the discharging valve 19 can be conveniently kept fixed, the tank body 5 in the turnover state can be conveniently fed and discharged, the tank bodies 5 on the left side and the right side of the rotating ring 17 can be kept in an integral synchronous rotating state, and the supporting rod 21 can support the discharging pipe 20.

As shown in fig. 6 to 7, as a preferable mode of the above embodiment, the guiding structure includes a connecting ball 22 rotatably embedded on an outer wall of the rotating ring 17, a telescopic rod 23 is fixed on an outer wall of the connecting ball 22, the telescopic rod 23 is perpendicular to the vertical plate 6, and a first plate spring 24 is connected between a fixed end and a movable end of the telescopic rod 23;

a first guide rail 25 is transversely arranged on the side wall of the vertical plate 6, a second guide rail 26 is vertically arranged on the first guide rail 25, the second guide rail 26 slides on the first guide rail 25, a sliding block 27 is arranged on the second guide rail 26 in a sliding manner, and the sliding block 27 is connected with the fixed end of the telescopic rod 23.

Specifically, the first plate spring 24 generates elastic tension to the movable end and the fixed end of the telescopic rod 23, so that the telescopic rod 23 is kept perpendicular to the vertical plate 6, at this time, when the tank body 5 is at any position, the distance between the connecting ball 22 and the vertical plate 6 is kept in the shortest state, so that the position of the rotating ring 17 is limited and guided, meanwhile, the rotating ring 17 can drive the sliding block 27 to slide on the second guide rail 26 through the connecting ball 22 and the telescopic rod 23, and the second guide rail 26 can slide on the first guide rail 25.

As shown in fig. 5, as a preferred embodiment, a sliding sleeve 28 is slidably disposed on an outer wall of the main shaft 1, two right-angle top plates 29 are oppositely disposed on an outer wall of the sliding sleeve 28, a connecting line between the two right-angle top plates 29 is perpendicular to a rotation axis direction of the first U-shaped frame 2 on the main shaft 1, and a second plate spring 30 is connected between the sliding sleeve 28 and the main shaft 1.

Specifically, when first U type frame 2 rotates the minimum angle on main shaft 1, first U type frame 2 and the contact of right angle roof 29, 2 accessible right angle roof 29 of first U type frame at this moment promote sliding sleeve 28 and slide on main shaft 1, elastic deformation takes place for second leaf spring 30, through setting up sliding sleeve 28, right angle roof 29 and second leaf spring 30, can produce reverse elastic thrust to first U type frame 2 when minimum angle between first U type frame 2 and main shaft 1, thereby conveniently make first U type frame 2 antiport on main shaft 1, avoid first U type frame 2 and main shaft 1 the dead phenomenon of card to appear, guarantee equipment continuous operation.

As shown in fig. 5, as a preferred embodiment, a plurality of sliding ribs 31 are fixed on the outer wall of the main shaft 1, the sliding ribs 31 penetrate through the sliding sleeve 28, the sliding sleeve 28 slides on the sliding ribs 31, an arched stop plate 32 spans outside the sliding sleeve 28, and the arched stop plate 32 is fixed on the outer wall of the main shaft 1.

Specifically, through setting up smooth arris 31, can conveniently lead spacing processing for sliding sleeve 28 to make sliding sleeve 28 and main shaft 1 synchronous rotation, bow-shaped limiting plate 32 can carry out spacing processing to sliding sleeve 28's position.

As shown in fig. 2, as a preferred embodiment, a cover 33 is disposed on the side wall of the vertical plate 6, and the cover 33 is located outside the circular groove plate 8, the motor 10, the first spur gear 11, the second spur gear 12, the transmission shaft 13, the bevel gear 14 and the bevel ring gear 15.

Specifically, through setting up dustcoat 33, can conveniently shelter from the protection to the structure of riser 6 back mounted.

The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, several modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the protection scope of the present invention.

Claims (8)

1. The solidification prevention buffer tank for processing the composite material is characterized by comprising two main shafts (1), wherein the two main shafts (1) are horizontal, the two main shafts (1) are parallel, a first U-shaped frame (2) is rotatably arranged at the end part of each main shaft (1), a connecting arm (3) is fixed on each first U-shaped frame (2), a second U-shaped frame (4) is fixed at the outer end of each connecting arm (3), a tank body (5) is arranged between the two second U-shaped frames (4), and the tank body (5) is rotatably connected with the second U-shaped frames (4);

the rotating axis of the tank body (5) on the second U-shaped frame (4) is vertical to the rotating axis of the first U-shaped frame (2) on the main shaft (1).

2. The composite material processing anti-solidification buffer tank is characterized by further comprising vertical plates (6), wherein the two main shafts (1) penetrate through the vertical plates (6), the main shafts (1) are rotatably connected with the vertical plates (6), a connecting shaft (7) is fixed at the end part of one vertical plate (6), a circular groove plate (8) is buckled at the outer side of the connecting shaft (7), the connecting shaft (7) is rotatably connected with the circular groove plate (8), and a torsion spring (9) is connected between the connecting shaft (7) and the circular groove plate (8);

wherein the diameter of the circular slotted plate (8) is equal to that of the main shaft (1).

3. The anti-solidification buffer tank for processing the composite material as claimed in claim 2, wherein a motor (10) is fixed on the side wall of the vertical plate (6), a first straight gear (11) is arranged at the output end of the motor (10), a second straight gear (12) is arranged on the first straight gear (11) in a meshed manner, a transmission shaft (13) is arranged on the second straight gear (12), the transmission shaft (13) is rotatably installed on the vertical plate (6), bevel gears (14) are arranged at both ends of the transmission shaft (13), bevel gear rings (15) are arranged on the bevel gears (14) in a meshed manner, one of the bevel gear rings (15) is fixed on the main shaft (1), and the other bevel gear ring (15) is fixed on the circular groove plate (8).

4. The anti-solidification buffer tank for processing the composite material as claimed in claim 3, wherein a plurality of through openings (16) are formed in the middle of the outer wall of the tank body (5), the plurality of through openings (16) are distributed in an annular shape, a rotating ring (17) is rotatably sleeved in the middle of the outer wall of the tank body (5), the rotating ring (17) blocks the through openings (16), a feeding valve (18) and a discharging valve (19) are arranged on the outer wall of the rotating ring (17), a discharging pipe (20) is communicated with the discharging valve (19), a support rod (21) is fixed on the side wall of the vertical plate (6), and the outer end of the support rod (21) is connected with the discharging pipe (20);

wherein, be provided with guide structure on the riser (6) lateral wall, guide structure is used for carrying out spacing direction to swivel becket (17), makes swivel becket (17) and jar body (5) relative rotation.

5. The composite material processing solidification-prevention cache tank as claimed in claim 4, wherein the guiding structure comprises a connecting ball (22) rotatably embedded on the outer wall of the rotating ring (17), a telescopic rod (23) is fixed on the outer wall of the connecting ball (22), the telescopic rod (23) is perpendicular to the vertical plate (6), and a first plate spring (24) is connected between the fixed end and the movable end of the telescopic rod (23);

the side wall of the vertical plate (6) is transversely provided with a first guide rail (25), the first guide rail (25) is vertically provided with a second guide rail (26), the second guide rail (26) slides on the first guide rail (25), the second guide rail (26) is provided with a sliding block (27) in a sliding manner, and the sliding block (27) is connected with the fixed end of the telescopic rod (23).

6. The composite material processing anti-solidification buffer tank is characterized in that a sliding sleeve (28) is arranged on the outer wall of the main shaft (1) in a sliding mode, two right-angle top plates (29) are oppositely arranged on the outer wall of the sliding sleeve (28), a connecting line between the two right-angle top plates (29) is perpendicular to the direction of a rotating axis of the first U-shaped frame (2) on the main shaft (1), and a second plate spring (30) is connected between the sliding sleeve (28) and the main shaft (1).

7. The composite material processing anti-solidification buffer tank as claimed in claim 6, wherein a plurality of sliding ribs (31) are fixed on the outer wall of the main shaft (1), the sliding ribs (31) penetrate through the sliding sleeve (28), the sliding sleeve (28) slides on the sliding ribs (31), an arched limiting plate (32) spans the outer side of the sliding sleeve (28), and the arched limiting plate (32) is fixed on the outer wall of the main shaft (1).

8. The composite material processing is with preventing solidifying buffer tank of claim 7, characterized by, that is provided with dustcoat (33) on the lateral wall of riser (6), dustcoat (33) are located the outside of circular slotted plate (8), motor (10), first spur gear (11), second spur gear (12), transmission shaft (13), bevel gear (14) and awl ring gear (15).

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