CN110802739B - Mud solidification mixing arrangement for building engineering - Google Patents

Abstract

The invention discloses a slurry curing and mixing device for building engineering, which comprises a support frame, wherein the middle part of the bottom surface of the support frame is fixedly connected with a driving motor through a bolt, the top end of the support frame is fixedly connected with a support plate, and the output end of the driving motor penetrates through the bottom of the support plate and extends to the position above the top surface of the support plate. The invention relates to the field of constructional engineering equipment. This mud solidification mixing arrangement for building engineering passes through the rotatory drive V-arrangement driving medium of driving motor, drives the swing of swing ring, impel two reciprocating motion of supplying with the intracavity piston head, the process of automatic feeding in the mixed cover shell has been realized, the mobility of fluid in the mixed cover shell of swing increase through the swing of swing piece, the mixed effect has been promoted, and it is rotatory to have further accelerated the stirring mixing process through central spherical piece drive puddler, the mixing efficiency has been promoted, make the mixed effect more even. This has solved the unsatisfactory problem of current mud mixing arrangement mixing effect.

Description

Mud solidification mixing arrangement for building engineering

Technical Field

The invention relates to the field of constructional engineering equipment, in particular to a slurry curing and mixing device for constructional engineering.

Background

The construction engineering usually needs to use the slurry in the building process, and can also produce a large amount of slurry in the building construction process of building, and under the natural condition, the natural curing of the slurry needs a large amount of time, and the chemical agent and the slurry are mixed to accelerate the slurry curing, so that the engineering time is saved, and the engineering construction process is accelerated.

Most of the existing mixing devices for slurry solidification only adopt a stirring rod or a screw rod for stirring, the problems of heavy solute, poor fluidity and easy layering of slurry are ignored in the stirring process, and good mixing effect is difficult to realize after a solidification additive is added in the mixing process, so that the slurry is not uniform in solidification time in the solidification process and is easy to collapse.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a slurry curing and mixing device for building engineering, which solves the problem that the mixing effect of the existing slurry mixing device is not ideal.

In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides a mud solidification mixing arrangement for building engineering, includes the support frame, bolt fixedly connected with driving motor is passed through at the middle part of the bottom surface of support frame, the top fixedly connected with backup pad of support frame, driving motor's output runs through the bottom of backup pad and extends to its top surface top.

The top surface of the supporting plate is fixedly connected with a supply mechanism.

The top end of the supply mechanism is fixedly connected with a mixing mechanism, and the mixing mechanism is in transmission connection with the supply mechanism.

Preferably, the support frame is of a hollow structure, the top surface and the bottom surface of the support frame are both circular, and the diameter of the top surface of the support frame is smaller than that of the bottom surface of the support frame.

Preferably, the feeding mechanism comprises a feeding cylinder, the bottom surface of the feeding cylinder is fixedly connected with the top surface of the supporting plate, two supply cavities which are axially symmetrical about the central line of the supply cylinder are arranged in the supply cylinder, one-way valves communicated with the front surface and one side of the bottom end of each supply cavity are fixedly inserted in the front surface and one side of the bottom end of each supply cavity, the conduction directions of the two one-way valves are opposite, a piston head is movably sleeved in the supply cavity, the piston head is of a hollow structure, a rubber round pad is fixedly connected at the bottom end of the piston head, the interior of the piston head is movably sleeved with a conical surface piece, the circle center of the conical surface piece is movably lapped with a first spherical piece, the top surface welding of first spherical piece has the linkage piston rod, the top of linkage piston rod runs through the top of conical surface spare and extends to and supplies the chamber top, the top welding of linkage piston rod has the spherical piece of second.

The axis of the supply cylinder is movably inserted with a middle shaft rod, the bottom end of the middle shaft rod is welded with the output end of the driving motor, and the top end of the middle shaft rod penetrates through the top end of the supply cylinder and extends to the upper side of the supply cylinder.

Preferably, the conduction direction of the one-way valve on the left side of the supply column is from right to left, the conduction direction of the one-way valve on the left side of the front side of the supply column is from front to back, the conduction direction of the one-way valve on the right side of the front side of the supply column is from back to front, and the conduction direction of the one-way valve on the right side of the supply column is from right to left.

Preferably, the diameters of the first spherical member and the second spherical member are equal, and the diameter of the first spherical member should be larger than the diameter of the interlocking piston rod.

Preferably, the mixing mechanism comprises a hemispherical casing, the hemispherical casing is welded on the back of the top end of the supply cylinder, the front of the hemispherical casing is a concave surface, the front of the hemispherical casing is provided with an annular guide rail, the left side and the right side of the bottom end of the annular guide rail are respectively fixedly connected and communicated with the top ends of the two supply cavities, a swing ring is movably sleeved in the hemispherical casing, the left side and the right side of the swing ring are respectively and fixedly connected with a slide block, the two slide blocks are respectively and slidably connected with the annular guide rail, the bottom end of the swing ring is fixedly connected with a cone sleeve, the left side and the right side of the bottom surface of the cone sleeve are respectively and movably connected with two second spherical pieces, a swing shaft rod is movably sleeved at the center of the bottom end of the cone sleeve, the bottom end of the swing shaft rod penetrates through the middle part of the bottom surface of the inner wall, and one end of the V-shaped transmission part, which is back to the swinging shaft lever, is fixedly sleeved at the top end of the middle shaft lever.

The top surface of the swing ring is welded with a mixed casing, the left side and the right side of the top of the mixed casing are fixedly inserted with two transmission hoses, the other ends of the two transmission hoses are respectively fixedly connected and communicated with the one-way valves at the opposite sides of the two supply cavities, the middle part of the top surface of the inner wall of the mixed casing is fixedly inserted with a mixed center rod, the surface of the bottom end of the mixed center rod is in interference fit with a linking round table through a bearing, the side surface of the linking round table is movably inserted with three stirring rods in an annular array by taking the circle center of the linking round table as the center, the surface of each stirring rod is fixedly sleeved with a conical surface transmission sleeve, a central spherical part is movably lapped at the circle center of the bottom surface of the linking round table and is welded at the top end of the swing shaft rod, the surface of each central spherical part is in transmission connection with the side surfaces of the three, the outer edge of the limiting sleeve ring is fixedly sleeved with a sealing circular sleeve, the top end of the sealing circular sleeve is fixedly connected with the top surface of the inner wall of the mixing casing, the bottom surface of the sealing circular sleeve is fixedly connected with a sealing rubber sleeve, and the swinging shaft rod penetrates through the center of the sealing rubber sleeve and is in sealing connection with the sealing rubber sleeve.

Preferably, the outer diameter of the swinging ring is equal to the diameter of the inner ring of the annular guide rail, and the inner diameter of the swinging ring is equal to the maximum diameter of the cone sleeve.

Preferably, the included angle formed by the straight edges at the two sides of the end head of the V-shaped driving part is 135 degrees, and the side length of the edge where the V-shaped driving part is mutually connected with the swinging shaft rod is less than half of the radius of the swinging ring.

Advantageous effects

The invention provides a slurry curing and mixing device for building engineering. Compared with the prior art, the method has the following beneficial effects:

(1) this mud solidification mixing arrangement for building engineering passes through the rotatory V-arrangement driving medium of driving motor rotation drive, drives the swing ring swing, makes two reciprocating motion of supplying with the intracavity piston head, has realized mixing the interior automatic feeding's of cover shell process, and the raw materials interpolation is more high-efficient simple and convenient during the mixing.

(2) The mud solidification mixing arrangement for building engineering can effectually increase the mobility of the fluid in the mixing housing in the wobbling in-process of swing ring, impels the intensive mixing with the solidification additive of mud in the mixing housing, and its mixed mode is high-efficient abundant.

(3) This mud solidification mixing arrangement for building engineering passes through the rotation action of central spherical piece for conical surface transmission cover, makes conical surface transmission cover rotatory and drive the puddler and rotate, and rotatory puddler has accelerated the mixing process of mixing the inside fluid matter of cover shell, has promoted the mixing efficiency of device, and it is better to mix the effect.

Drawings

FIG. 1 is a front cross-sectional view of the structure of the present invention;

FIG. 2 is an enlarged view of the structure A of FIG. 1 according to the present invention;

fig. 3 is a top view of the present invention structural countersunk sleeve.

In the figure: 1. a support frame; 2. a drive motor; 3. a support plate; 4. a supply mechanism; 401. a supply cylinder; 402. a supply chamber; 403. a one-way valve; 404. a piston head; 405. a rubber round pad; 406. a conical member; 407. a first spherical member; 408. a linkage piston rod; 409. a second spherical member; 410. a middle shaft lever; 5. a mixing mechanism; 501. a hemispherical casing; 502. an annular guide rail; 503. a swing ring; 504. a slider; 505. a cone cover; 506. a swing shaft lever; 507. a V-shaped transmission member; 508. a mixing housing; 509. a transfer hose; 510. mixing the central rod; 511. connecting the circular truncated cones; 512. a stirring rod; 513. a conical surface transmission sleeve; 514. a central spherical member; 515. a limiting lantern ring; 516. sealing the round sleeve; 517. and (5) sealing the rubber sleeve.

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.

Referring to fig. 1-3, a slurry curing and mixing device for building engineering comprises a support frame 1, a driving motor 2 is fixedly connected to the middle of the bottom surface of the support frame 1 through a bolt, a support plate 3 is fixedly connected to the top end of the support frame 1, and the output end of the driving motor 2 penetrates through the bottom of the support plate 3 and extends to the top of the support plate.

The top surface of the support plate 3 is fixedly connected with a supply mechanism 4.

The top end of the supply mechanism 4 is fixedly connected with a mixing mechanism 5, and the mixing mechanism 5 is in transmission connection with the supply mechanism 4.

In the invention, the support frame 1 is of a hollow structure, the top surface and the bottom surface of the support frame 1 are both circular, the diameter of the top surface of the support frame 1 is smaller than that of the bottom surface of the support frame, the gravity of the equipment body is shared by a trapezoid structure with a small top and a big bottom, and the stability of the equipment during installation and support is improved.

In the invention, a supply mechanism 4 comprises a supply cylinder 401, the bottom surface of the supply cylinder 401 is fixedly connected with the top surface of a support plate 3, two supply cavities 402 which are axisymmetric with the center line of the supply cylinder 401 are arranged in the supply cylinder 401, the front surface and one side of the bottom end of each supply cavity 402 are fixedly inserted with a one-way valve 403 communicated with the same, the conduction directions of the two one-way valves 403 are opposite, a piston head 404 is movably sleeved in each supply cavity 402, automatic feeding and discharging of equipment can be realized through the alternate reciprocating action of the two piston heads 404 in the two supply cavities 402, the piston head 404 is of a hollow structure, the bottom end of the piston head 404 is fixedly connected with a rubber round pad 405, the rubber round pad 405 realizes the sealing effect of the piston head 404, a conical surface piece 406 is movably sleeved in the piston head 404, a first spherical piece 407 is movably overlapped at the circle center of the conical surface piece 406, and the specific action form of a linkage piston rod 408 The conical member 406 is provided to match the first spherical member 407, the interlocking piston rod 408 is welded to the top surface of the first spherical member 407, the tip of the interlocking piston rod 408 extends above the supply chamber 402 through the tip of the conical member 406, and the second spherical member 409 is welded to the tip of the interlocking piston rod 408.

The axis of the supply cylinder 401 is movably inserted with a middle shaft rod 410, the bottom end of the middle shaft rod 410 is welded with the output end of the driving motor 2, and the top end of the middle shaft rod 410 penetrates through the top end of the supply cylinder 401 and extends to the upper side of the supply cylinder.

In the present invention, the feed column left check valve 403 is conducted from right to left, the feed column front left check valve 403 is conducted from front to back, the feed column front right check valve 403 is conducted from back to front, and the feed column right check valve 403 is conducted from right to left.

In the invention, the diameters of the first spherical member 407 and the second spherical member 409 are equal, and the diameter of the first spherical member 407 is larger than the diameter of the linkage piston rod 408, so as to ensure the engagement and movement effects of the linkage piston rod 408, the conical surface member 406 and the cone sleeve 505.

In the invention, the mixing mechanism 5 comprises a hemispherical shell 501, the hemispherical shell 501 is welded on the back of the top end of the supply cylinder 401, the front surface of the hemispherical shell 501 is a concave surface, the diameter of the concave surface is larger than the outer diameter of the swing ring 503, the front surface of the hemispherical shell 501 is provided with an annular guide rail 502, the left side and the right side of the bottom end of the annular guide rail 502 are respectively fixedly connected and communicated with the top ends of the two supply cavities 402, the swing ring 503 is movably sleeved in the hemispherical shell 501, the swing ring 503 is a circular ring, the plane of the surface of the swing ring 503 is always intersected with the plane of the front surface of the hemispherical shell 501, the left side and the right side of the swing ring 503 are respectively and fixedly connected with a slide block 504, the two slide blocks 504 are respectively connected with the annular guide rail 502 in a sliding manner, the bottom end of the swing ring 503 is fixedly connected with a cone sleeve 505, the left side and the right side of the bottom surface of, the inner diameter of the spherical groove is larger than the diameter of the second spherical part 409, but the opening diameter of the bottom surface of the spherical groove is smaller than the diameter of the second spherical part 409, the linkage piston rod 408 is movably inserted into the opening of the bottom surface of the spherical groove, the center of the bottom end of the conical surface sleeve is movably sleeved with the swinging shaft rod 506, the bottom end of the swinging shaft rod 506 penetrates through the middle part of the bottom surface of the inner wall of the conical surface sleeve and extends to the lower part of the inner wall of the conical surface sleeve, the surface of the bottom end of the swinging shaft rod 506 is fixedly sleeved with the V-shaped transmission part 507, and the end of the V-shaped.

A mixing casing 508 is welded on the top surface of the swinging ring 503, the mixing casing 508, the swinging ring 503 and the cone sleeve 505 are combined together to form a closed cavity, the cavity is used for filling pouring slurry and curing additives, mixing and stirring are carried out in the cavity, two transmission hoses 509 are fixedly inserted on the left side and the right side of the top of the mixing casing 508, the other ends of the two transmission hoses 509 are respectively and fixedly connected and communicated with one-way valves 403 on the opposite sides of the two supply cavities 402, a mixing center rod 510 is fixedly inserted in the middle of the top surface of the inner wall of the mixing casing 508, the mixing center rod 510 revolves around the center shaft 410 along with the driving of the V-shaped driving piece 507, the mixing center rod 510 drives the center ball 514 to rotate relative to the cone driving sleeve 513 in the rotation process, the three cone driving sleeves 513 are mutually extruded and attached to the center ball 514, the rotation of the cone driving sleeve 513, the surface of the bottom end of the mixed center rod 510 is in interference fit with an engaging circular truncated cone 511 through a bearing, the side surface of the engaging circular truncated cone 511 is movably inserted with three stirring rods 512 in an annular array by taking the circle center of the engaging circular truncated cone 511 as the center, the surface of each stirring rod 512 is fixedly sleeved with a conical surface transmission sleeve 513, a central spherical part 514 is movably overlapped at the circle center of the bottom surface of the engaging circular truncated cone 511, the central spherical part 514 is welded at the top end of the swinging shaft 506, the surface of the central spherical part 514 is in transmission connection with the side surfaces of the three conical surface transmission sleeves 513, a limit collar 515 is movably connected with the side surface of the three conical surface transmission sleeves 513 departing from the circle center of the engaging circular truncated cone 511, the engaging effect of the three conical surface transmission sleeves 513 is enhanced through the limit collar 515, the three conical surface transmission sleeves 513 can be tightly attached to the central spherical part 514, the self rotating effect can be, the top of sealed circle cover 516 and the top surface fixed connection of mixing the shell 508 inner wall, the bottom surface fixed connection of sealed circle cover 516 has sealed gum cover 517, and swing axostylus axostyle 506 runs through the center of sealed gum cover 517 and with sealed gum cover 517 sealing connection.

In the present invention, the outer diameter of the swing ring 503 is equal to the diameter of the inner ring of the ring guide 502, and the inner diameter of the swing ring 503 is equal to the maximum diameter of the taper sleeve 505.

In the invention, the included angle formed by the straight edges at the two sides of the end head of the V-shaped driving element 507 is 135 degrees, and the side length of the side where the V-shaped driving element 507 and the swinging shaft lever 506 are mutually connected is less than half of the radius of the swinging ring 503.

When the device is used, the output end of the driving motor 2 rotates to drive the middle shaft lever 410 to rotate, the middle shaft lever 410 drives the V-shaped transmission piece 507 to rotate, the V-shaped transmission piece 507 drives the swinging ring 503 to reciprocate left and right, meanwhile, the sliding block 504 slides in the annular guide rail 502 to drive the swinging ring 503 to realize a swinging effect, the swinging ring 503 drives the mixing casing 508 to swing to accelerate mixing between slurry and a curing additive in the mixing casing 508, the cone sleeve 505 synchronously moving with the swinging ring 503 drives the linkage piston rods 408 on the left side and the right side to reciprocate, so that the two piston heads 404 sequentially reciprocate in the two supply cavities 402 to input and output fluid into and out of the mixing casing 508, due to the swinging of the swinging ring 503, the central spherical piece 514 rotates relative to the cone transmission sleeve 513 and drives the cone transmission sleeve 513 to rotate, so that the cone transmission sleeve 513 drives the stirring rod 512 to rotate, and the stirring rod 512 further stirs and mixes fluid flowing in the, accelerate the mixing speed and improve the mixing uniformity.

Due to the restriction of the flow direction of the check valve 403, after the slurry and the curing additive are mixed, the slurry and the curing additive enter the left side supply cavity 402 through the left side check valve 403 on the front side of the supply cylinder 401, are pressed by the left side piston head 404 and enter the mixing casing 508 from the left side check valve 403 on the supply cylinder 401 through the delivery hose 509, and when the fluid in the mixing casing 508 flows to the insertion position of the delivery hose 509 on the right side after mixing and stirring, the right side piston head 404 extracts the mixed slurry and pushes the mixed slurry into the right side supply cavity 402 through the right side check valve 403 on the supply cylinder 401, and finally the mixed slurry is pushed out of the equipment through the right side check valve 403 on.

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.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that 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 (6)

1. The utility model provides a mud solidification mixing arrangement for building engineering, includes support frame (1), its characterized in that: the middle part of the bottom surface of the support frame (1) is fixedly connected with a driving motor (2) through a bolt, the top end of the support frame (1) is fixedly connected with a support plate (3), and the output end of the driving motor (2) penetrates through the bottom of the support plate (3) and extends to the upper part of the top surface of the support plate;

the top surface of the supporting plate (3) is fixedly connected with a supply mechanism (4);

the feeding mechanism (4) comprises a feeding cylinder (401), the bottom surface of the feeding cylinder (401) is fixedly connected with the top surface of the supporting plate (3), two feeding cavities (402) which are axisymmetric with the center line of the feeding cylinder (401) are formed in the feeding cylinder (401), one-way valves (403) communicated with the feeding cavities (402) are fixedly inserted in the front surface and one side of the bottom end of each feeding cavity (402), the two one-way valves (403) are opposite in conduction direction, a piston head (404) is movably sleeved in each feeding cavity (402), the piston head (404) is of a hollow structure, a rubber round cushion (405) is fixedly connected to the bottom end of each piston head (404), a conical surface piece (406) is movably sleeved in the piston head (404), a first spherical piece (407) is movably overlapped at the circle center of each conical surface piece (406), and a linkage piston rod (408) is welded on the top surface of each first spherical piece (407), the top end of the linkage piston rod (408) penetrates through the top end of the conical surface piece (406) and extends to the upper part of the supply cavity (402), and a second spherical piece (409) is welded to the top end of the linkage piston rod (408);

a middle shaft rod (410) is movably inserted in the axis of the supply cylinder (401), the bottom end of the middle shaft rod (410) is welded with the output end of the driving motor (2), and the top end of the middle shaft rod (410) penetrates through the top end of the supply cylinder (401) and extends to the upper side of the supply cylinder;

the top end of the supply mechanism (4) is fixedly connected with a mixing mechanism (5), and the mixing mechanism (5) is in transmission connection with the supply mechanism (4);

the mixing mechanism (5) comprises a hemispherical casing (501), the hemispherical casing (501) is welded on the back of the top end of the supply cylinder (401), the front surface of the hemispherical casing (501) is a concave surface, the front surface of the hemispherical casing (501) is provided with an annular guide rail (502), the left side and the right side of the bottom end of the annular guide rail (502) are respectively fixedly connected and communicated with the top ends of two supply cavities (402), a swing ring (503) is movably sleeved in the hemispherical casing (501), the left side and the right side of the swing ring (503) are respectively and fixedly connected with a sliding block (504), the two sliding blocks (504) are respectively and slidably connected with the annular guide rail (502), the bottom end of the swing ring (503) is fixedly connected with a cone sleeve (505), the left side and the right side of the bottom surface of the cone sleeve (505) are respectively and movably connected with two second conical surface pieces (409), and a swing shaft lever (506) is movably sleeved, the bottom end of the swinging shaft lever (506) penetrates through the middle part of the bottom surface of the inner wall of the conical sleeve and extends to the lower part of the conical sleeve, a V-shaped transmission piece (507) is fixedly sleeved on the surface of the bottom end of the swinging shaft lever (506), and one end, opposite to the swinging shaft lever (506), of the V-shaped transmission piece (507) is fixedly sleeved on the top end of the middle shaft lever (410);

the top surface of the swinging ring (503) is welded with a mixed casing (508), the left side and the right side of the top of the mixed casing (508) are fixedly inserted with two transmission hoses (509), the other ends of the two transmission hoses (509) are respectively and fixedly connected and communicated with the one-way valve (403) at the opposite sides of the two supply cavities (402), the middle part of the top surface of the inner wall of the mixed casing (508) is fixedly inserted with a mixed central rod (510), the surface of the bottom end of the mixed central rod (510) is in interference fit with a linking round platform (511) through a bearing, the side surface of the linking round platform (511) is movably inserted with three stirring rods (512) in an annular array by taking the circle center of the linking round platform (511) as the center, the surface of each stirring rod (512) is fixedly sleeved with a conical surface transmission sleeve (513), and a central spherical part (514) is movably, the utility model discloses a mixing sleeve, including swing axle lever (506), center spherical piece (514), three conical surface transmission cover (513) and the top surface swing joint who links up the round platform (511) centre of a circle, the spherical piece of center (514) welds the top at swing axle lever (506), the surface of center spherical piece (514) and three the side surface of conical surface transmission cover (513) all becomes the transmission and is connected, three the side surface swing joint that conical surface transmission cover (513) deviates from linking round platform (511) centre of a circle has spacing lantern ring (515), sealed round cover (516) have been cup jointed along fixed outward of spacing lantern ring (515), the top of sealed round cover (516) and the top surface fixed connection of mixing shell (508) inner wall, the bottom surface fixedly connected with of sealed round cover (516) seals gum cover (517), swing axle lever (506.

2. The mud curing and mixing device for the building engineering as claimed in claim 1, wherein: the supporting frame (1) is of a hollow structure, the top surface and the bottom surface of the supporting frame (1) are both circular, and the diameter of the top surface of the supporting frame (1) is smaller than that of the bottom surface of the supporting frame.

3. The mud curing and mixing device for the building engineering as claimed in claim 1, wherein: the conduction direction of the check valve (403) on the left side of the supply column is from right to left, the conduction direction of the check valve (403) on the left side of the front of the supply column is from front to back, the conduction direction of the check valve (403) on the right side of the front of the supply column is from back to front, and the conduction direction of the check valve (403) on the right side of the supply column is from right to left.

4. The mud curing and mixing device for the building engineering as claimed in claim 1, wherein: the diameters of the first spherical member (407) and the second spherical member (409) are equal, and the diameter of the first spherical member (407) is larger than the diameter of the linkage piston rod (408).

5. The mud curing and mixing device for the building engineering as claimed in claim 1, wherein: the outer diameter of the swinging ring (503) is equal to the diameter of the inner ring of the annular guide rail (502), and the inner diameter of the swinging ring (503) is equal to the maximum diameter of the cone sleeve (505).

6. The mud curing and mixing device for the building engineering as claimed in claim 1, wherein: the included angle formed by the straight edges at the two sides of the end head of the V-shaped transmission part (507) is 135 degrees, and the side length of the side where the V-shaped transmission part (507) is mutually connected with the swinging shaft lever (506) is less than half of the radius of the swinging ring (503).

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