CN210636797U - Bottom support fixing device of high hanging die - Google Patents

Abstract

The utility model discloses a high bottom sprag fixing device who hangs mould relates to and hangs the fixed technical field of mould. The utility model comprises an outer support frame and an inner support frame; a supporting mechanism is also arranged between the inner supporting frame and the inner template; the supporting mechanism comprises an adjusting mechanism and an auxiliary mechanism. The utility model makes the vertical block of the L-shaped sliding block completely slide out of the first convex sliding groove by extending the first electric telescopic rod, and then the stepping motor rotates to drive the screw rod to rotate so as to make the inner membrane plate move downwards; when wanting to get back to horizontal spout structure to the inner membrance board, step motor drives the rotatory inner membrance board that makes of screw rod direction and upwards removes, and when the inner membrance board rises back to horizontal spout structure top, first electric telescopic handle shrink is close to the inner membrance board to second montant direction, and is convenient, is convenient for hang the high-efficient installation and the dismantlement of mould.

Description

Bottom support fixing device of high hanging die

Technical Field

The utility model belongs to the technical field of hang the mould fixed, especially relate to a high bottom sprag fixing device who hangs the mould.

Background

When a high-rise building is constructed, efficient building construction is realized by hoisting a mould through a tower crane; in fact, the method belongs to the prior fabric mould for pouring concrete. The suspension mould generally comprises an inner mould and an outer mould, and a pouring space formed by the outer mould and the inner mould is convenient to pour after fixed packaging; besides the inner die and the outer die, the inner die also comprises a supporting and fixing frame for fixing the outer die and the inner die; in the using process of the suspended formwork, the processes of pouring and formwork removal are repeatedly carried out; in this case, the outer formwork is generally fixed and the inner formwork is movable during production. A good mould fixing device that hangs can improve the efficiency of hanging the mould construction.

The utility model provides a bottom sprag fixing device of high mould that hangs realizes hanging convenient form removal and the fixed mould that hangs in the mould construction process.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a high bottom sprag fixing device who hangs mould, still adorn supporting mechanism between outer support frame and inner support frame and the inner formword that "well" word roof beam is connected, and supporting mechanism's adjustment mechanism and complementary unit adjust, realize hanging convenient form removal and fixed of mould construction in-process.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme:

the utility model relates to a bottom supporting and fixing device of a high hanging mould, which comprises four outer templates positioned at the outer side and four inner templates positioned at the inner side; the four outer templates are not connected with each other and are distributed in a rectangular shape; the outer template and the inner template are distributed in the same way and are parallel to each other; further comprising: an outer support frame and an inner support frame; a supporting mechanism is also arranged between the inner supporting frame and the inner template;

the outer support frame comprises a cross beam positioned at the top; any end of the cross beam is connected with a first vertical rod; the first vertical rods are distributed in a rectangular shape and are positioned outside the outer template; the first vertical rods are connected through a plurality of parallel rectangular outer ring frames; the rectangular outer ring frame is connected with the outer template through a horizontal connecting rod;

the inner support frame comprises two rectangular inner ring frames which are positioned in the four inner templates, are distributed up and down and are parallel to each other; the two rectangular inner ring frames are connected through a second vertical rod; the second vertical rods are vertically connected to the lower bottom surface of the cross beam;

the supporting mechanism comprises an adjusting mechanism and an auxiliary mechanism; the adjusting mechanism comprises two parallel first vertical sliding chute structures; the first vertical sliding chute structure is a rectangular block-shaped structure with a rectangular sliding chute formed in one side surface; the rectangular sliding groove is matched with the L-shaped sliding block in a sliding mode;

a screw rod is installed on a vertical block thread of the L-shaped sliding block; the screw rod vertically penetrates through the vertical block; one end of the screw rod penetrates through a sliding hole formed in the top of the first vertical sliding groove structure and then is connected with a first gear; the first gear is meshed and connected with a horizontal rack fixed on one side of the inner template; a second gear meshed and connected with the horizontal rack is connected with the output end of the stepping motor;

the horizontal block of the L-shaped sliding block is matched with a first convex sliding groove formed in one surface of the horizontal sliding groove structure in a sliding mode; a first electric telescopic rod is arranged in the first convex sliding groove; the output end of the first electric telescopic rod is connected with one end of the horizontal block of the L-shaped sliding block; the horizontal sliding chute structure is vertically arranged on one side of the lower rectangular inner ring frame;

the auxiliary mechanism comprises a second vertical chute structure arranged on one side of the inner template; the second vertical sliding chute structure is a rectangular block structure with a second convex sliding chute formed in one side surface; the second convex sliding groove is matched with the convex sliding block in a sliding manner; one end of the convex sliding block is hinged with the output end of the second electric telescopic rod; and the second electric telescopic rod is vertically fixed at one side of the rectangular inner ring frame positioned above the second electric telescopic rod.

Preferably, the cross beams comprise two cross beams parallel to each other and two longitudinal beams parallel to each other; the cross beam and the longitudinal beam are mutually and vertically connected; first vertical rods are arranged at two ends of the cross beam and two ends of the longitudinal beam.

Preferably, the four outer templates are all positioned outside the rectangular outer ring frame; the outer templates correspond to the side edges of the rectangular outer ring frames one by one; the inner templates correspond to the sides of the rectangular inner ring frame one by one.

Preferably, the lower bottom surface of the first vertical chute structure is flush with the lower bottom surface of the inner formwork; the rectangular sliding groove penetrates through the lower bottom surface of the first vertical sliding groove structure.

Preferably, the second gear is at a midpoint position of the two first gears.

Preferably, the first convex chute penetrates through one side end of the horizontal chute structure; the minimum distance between two side walls of the first convex sliding chute is 2-3cm larger than that of the rectangular sliding chute.

The utility model discloses specific practical in-process: after the lifting die is placed at the corresponding position, the first electric telescopic rod extends to enable the vertical block of the L-shaped sliding block to completely slide out of the first convex sliding groove, and then the stepping motor rotates to drive the screw rod to rotate to enable the inner membrane plate to move downwards; when the inner membrane plate is required to return to the horizontal sliding groove structure, the stepping motor drives the screw rod to rotate in the direction so as to enable the inner membrane plate to move upwards, and when the inner membrane plate rises above the horizontal sliding groove structure, the first electric telescopic rod contracts to enable the inner membrane plate to approach the second vertical rod direction, so that the lifting mould is convenient and fast, and efficient installation and disassembly of the lifting mould are facilitated; in the whole process, the second electric telescopic rod is synchronous with the first electric telescopic rod in stretching, and the device is convenient and fast.

The utility model discloses following beneficial effect has:

1. the utility model discloses the outer support frame and the inner support frame that "well" word roof beam connects and still install the supporting mechanism between inner support frame and the inner formword, the adjustment mechanism and the auxiliary mechanism of supporting mechanism adjust, realize that hangs convenient form removal and fixing in the mould construction process;

2. in the utility model, after the lifting mould is placed at the corresponding position, the first electric telescopic rod extends to enable the vertical block of the L-shaped sliding block to completely slide out of the first convex sliding chute, and then the stepping motor rotates to drive the screw rod to rotate to enable the inner membrane plate to move downwards; when the inner membrane plate is required to return to the horizontal sliding groove structure, the stepping motor drives the screw rod to rotate in the direction so as to enable the inner membrane plate to move upwards, and when the inner membrane plate rises above the horizontal sliding groove structure, the first electric telescopic rod contracts to enable the inner membrane plate to approach the second vertical rod direction, so that the lifting mould is convenient and fast, and efficient installation and disassembly of the lifting mould are facilitated; in the whole process, the second electric telescopic rod is synchronous with the first electric telescopic rod in stretching, and the device is convenient and fast.

Of course, it is not necessary for any particular product to achieve all of the above-described advantages at the same time.

Drawings

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

Fig. 1 is a schematic structural view of a bottom supporting and fixing device of a high hanging mold of the present invention;

FIG. 2 is a front view of FIG. 1;

FIG. 3 is a top view of FIG. 1;

FIG. 4 is a schematic structural view of a support mechanism installed between the inner support frame and the inner formwork;

FIG. 5 is an enlarged view of A in FIG. 4;

fig. 6 is an enlarged view of a in fig. 4.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-6, the present invention relates to a bottom supporting and fixing device for a high hanging mold, which comprises four outer mold plates 1 located at the outer side and four inner mold plates 2 located at the inner side; the four outer templates 1 are not connected with each other and are distributed in a rectangular shape; the outer template 1 and the inner template 2 are distributed in the same way, and the outer template 1 and the inner template 2 are parallel; further comprising: an outer support frame and an inner support frame; a supporting mechanism is also arranged between the inner supporting frame and the inner template 2;

the outer support frame comprises a "well" beam 31 at the top; any end of the cross beam 31 is connected with a first vertical rod 32; the first vertical rods 32 are distributed in a rectangular shape and are positioned outside the outer template 1; the first vertical rods 32 are connected through a plurality of mutually parallel rectangular outer ring frames 33; the rectangular outer ring frame 33 is connected with the outer template 1 through a horizontal connecting rod 34;

the inner supporting frame comprises two rectangular inner ring frames 41 which are positioned in the four inner templates 2, are distributed up and down and are parallel to each other; the two rectangular inner ring frames 41 are connected through a second vertical rod 42; a plurality of second vertical rods 42 are vertically connected to the lower bottom surface of the cross beam 31;

the supporting mechanism comprises an adjusting mechanism and an auxiliary mechanism; the adjusting mechanism comprises two first vertical chute structures 51 which are parallel to each other; the first vertical sliding groove structure 51 is a rectangular block structure with a rectangular sliding groove formed in one side surface; the L-shaped sliding block 52 is matched in the rectangular sliding groove in a sliding way;

a vertical block thread mounting screw 53 of the L-shaped slide block 52; the screw 53 vertically penetrates through the vertical block; one end of the screw 53 passes through a sliding hole formed in the top of the first vertical sliding groove structure 51 and then is connected with a first gear 531; the first gear 531 is meshed with a horizontal rack 532 fixed on one side of the inner formwork 2; a second gear meshed and connected with the horizontal rack 532 is connected with the output end of the stepping motor 533;

the horizontal block of the L-shaped sliding block 52 is matched with a first convex sliding groove 541 formed in one surface of the horizontal sliding groove structure 54 in a sliding manner; a first electric telescopic rod 542 is arranged in the first convex sliding groove 541; the output end of the first electric telescopic rod 542 is connected with one end of the horizontal block of the L-shaped sliding block 52; the horizontal chute structure 54 is vertically installed at one side of the lower rectangular inner ring frame 41;

the auxiliary mechanism comprises a second vertical chute structure 61 arranged at one side of the inner template 2; the second vertical sliding groove structure 61 is a rectangular block structure with a second convex sliding groove 611 formed in one side surface; second male runner 611 slidably mates with male slider 612; one end of the convex sliding block 612 is hinged with the output end of the second electric telescopic rod 613; the second electric telescopic rod 613 is vertically fixed to one side of the upper rectangular inner ring frame 41.

The 'well' -shaped beam 31 comprises two parallel cross beams and two parallel longitudinal beams; the cross beam is vertically connected with the longitudinal beam; first vertical rods 32 are arranged at two ends of the cross beam and two ends of the longitudinal beam.

Wherein, the four outer templates 1 are all positioned at the outer side of the rectangular outer ring frame 33; the outer template 1 corresponds to the side edges of the rectangular outer ring frame 33 one by one; the inner templates 2 correspond to the sides of the rectangular inner ring frame 41 one by one.

Wherein, the lower bottom surface of the first vertical chute structure 51 is flush with the lower bottom surface of the inner template 2; the rectangular chute penetrates the lower bottom surface of the first vertical chute structure 51.

The second gear is located at the midpoint between the two first gears 531.

Wherein, the first convex chute 541 penetrates through one side end of the horizontal chute structure 54; the minimum distance between the two side walls of the first convex sliding chute 541 is 2-3cm larger than that of the rectangular sliding chute.

The utility model discloses specific practical in-process: after the hanging mould is placed at the corresponding position, the first electric telescopic rod 542 extends to enable the vertical block of the L-shaped sliding block 52 to completely slide out of the first convex sliding groove 541, and then the stepping motor 533 rotates to drive the screw 53 to rotate to enable the inner membrane plate 2 to move downwards; when the inner membrane plate 2 is required to return to the horizontal chute structure 54, the stepping motor 533 drives the screw 53 to rotate in the direction so as to enable the inner membrane plate 2 to move upwards, and when the inner membrane plate 2 is lifted to the position above the horizontal chute structure 54, the first electric telescopic rod 542 contracts to enable the inner membrane plate 2 to approach the second vertical rod 42, so that the mould hanging device is convenient and fast to use, and is convenient for efficient installation and disassembly of a hanging mould; in the whole process, the second electric telescopic rod 613 and the first electric telescopic rod 542 are synchronous in extension and retraction, and the electric telescopic rod is convenient and fast.

It should be noted that, in the above system embodiment, each included unit is only divided according to functional logic, but is not limited to the above division as long as the corresponding function can be implemented; in addition, the specific names of the functional units are also only for the convenience of distinguishing from each other, and are not used to limit the protection scope of the present invention.

The preferred embodiments of the present invention disclosed above are intended only to help illustrate the present invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The present invention is limited only by the claims and their full scope and equivalents.

Claims (6)

1. A bottom supporting and fixing device of a high hanging die comprises four outer die plates (1) positioned on the outer side and four inner die plates (2) positioned on the inner side; the four outer templates (1) are not connected with each other and are distributed in a rectangular shape; the outer template (1) and the inner template (2) are distributed in the same way, and the outer template (1) and the inner template (2) are parallel; it is characterized by also comprising: an outer support frame and an inner support frame; a supporting mechanism is also arranged between the inner supporting frame and the inner template (2);

the outer support frame comprises a cross beam (31) at the top; any end of the cross beam (31) is connected with a first vertical rod (32); the first vertical rods (32) are distributed in a rectangular shape and are positioned outside the outer template (1); the first vertical rods (32) are connected through a plurality of mutually parallel rectangular outer ring frames (33); the rectangular outer ring frame (33) is connected with the outer template (1) through a horizontal connecting rod (34);

the inner support frame comprises two rectangular inner ring frames (41) which are positioned in the four inner templates (2) and are distributed up and down and are parallel to each other; the two rectangular inner ring frames (41) are connected through a second vertical rod (42); the second vertical rods (42) are vertically connected to the lower bottom surface of the cross beam (31);

the supporting mechanism comprises an adjusting mechanism and an auxiliary mechanism; the adjusting mechanism comprises two first vertical sliding chute structures (51) which are parallel to each other; the first vertical sliding chute structure (51) is a rectangular block-shaped structure with a rectangular sliding chute formed in one side surface; the rectangular sliding groove is matched with an L-shaped sliding block (52) in a sliding manner;

a vertical block thread mounting screw rod (53) of the L-shaped sliding block (52); the screw (53) vertically penetrates through the vertical block; one end of the screw rod (53) passes through a sliding hole formed in the top of the first vertical sliding groove structure (51) and then is connected with a first gear (531); the first gear (531) is meshed with a horizontal rack (532) fixed on one side of the inner template (2); a second gear meshed and connected with the horizontal rack (532) is connected with the output end of the stepping motor (533);

the horizontal block of the L-shaped sliding block (52) is matched with a first convex sliding groove (541) formed in one surface of the horizontal sliding groove structure (54) in a sliding mode; a first electric telescopic rod (542) is arranged in the first convex sliding groove (541); the output end of the first electric telescopic rod (542) is connected with one end of a horizontal block of the L-shaped sliding block (52); the horizontal sliding chute structure (54) is vertically arranged on one side of the rectangular inner ring frame (41) positioned below;

the auxiliary mechanism comprises a second vertical chute structure (61) arranged on one side of the inner template (2); the second vertical sliding groove structure (61) is a rectangular block structure with a second convex sliding groove (611) formed in one side surface; said second male runner (611) sliding a mating male slider (612); one end of the convex sliding block (612) is hinged with the output end of the second electric telescopic rod (613); the second electric telescopic rod (613) is vertically fixed at one side of the upper rectangular inner ring frame (41).

2. A bottom support fixture for a high lift mould according to claim 1, characterised in that said cross beams (31) comprise two cross beams parallel to each other and two longitudinal beams parallel to each other; the cross beam and the longitudinal beam are mutually and vertically connected; first vertical rods (32) are arranged at two ends of the transverse beam and two ends of the longitudinal beam.

3. A bottom supporting and fixing device of a high suspended mould according to claim 1, characterized in that four outer mould plates (1) are all positioned outside a rectangular outer ring frame (33); the outer template (1) corresponds to the side edges of the rectangular outer ring frame (33) one by one; the inner templates (2) correspond to the sides of the rectangular inner ring frames (41) one by one.

4. A bottom support fixture of a high suspended form according to claim 1, characterized in that the lower bottom surface of the first vertical runner structure (51) is flush with the lower bottom surface of the inner formworks (2); the rectangular sliding groove penetrates through the lower bottom surface of the first vertical sliding groove structure (51).

5. A bottom support fixture of a high suspended mould according to claim 1, characterized in that the second gear is at the midpoint position of the two first gears (531).

6. A bottom support fixture for a high lift mould as claimed in claim 1, wherein said first male runner (541) extends through a side end of the horizontal runner structure (54); the minimum distance between the two side walls of the first convex sliding chute (541) is 2-3cm larger than that of the rectangular sliding chute.

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