CN217372765U - Integral bay window internal mold and bay window mold - Google Patents

Abstract

The utility model discloses an integral bay window centre form and bay window mould, wherein, this integral bay window centre form includes first concatenation module, second concatenation module and adjustment mechanism. The number of the first splicing modules is multiple; the quantity of second concatenation module is a plurality of, and is a plurality of second concatenation module interval sets up in adjacent two between the first concatenation module, and with adjacent two first concatenation module is connected, the second concatenation module has and is close to and keeps away from the first concatenation position and the second concatenation position of first concatenation module, and is a plurality of first concatenation module and a plurality of the second concatenation module encloses to close and forms the interior die face of pouring the space, adjustment mechanism connects a plurality ofly first concatenation module is used for driving first concatenation module is to being close to or keeping away from adjustment mechanism's direction removes. The utility model discloses the dismouting efficiency of bay window inner membrance can be greatly improved to integral bay window centre form to improve the production efficiency of prefabricated bay window.

Description

Integral bay window internal mold and bay window mold

Technical Field

The utility model relates to a building mould field, in particular to integral bay window centre form and bay window mould.

Background

Along with the increase of the implementation strength of the fabricated building, the diversification of the prefabricated components is gradually increased from the horizontal components to the vertical components. Bay windows are difficult to form on site as non-load bearing members and have poor forming quality, so more and more units tend to be prefabricated in the factory. At present, a bay window mould on the market mainly comprises an outer module, an inner module, a bottom mould group and a supporting tool, wherein the outer module, the inner module and the bottom mould group are respectively disassembled into a plurality of blocks and then are connected by a plurality of screw bolts, so that the mould is extremely complicated in assembly and disassembly. And the operation space is narrow and small, and the disassembly consumes a large amount of time, thereby seriously influencing the production efficiency of the prefabricated bay window.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an integral bay window centre form and bay window mould aims at solving the loaded down with trivial details difficult operation of the prefabricated mould dismouting of current bay window, influences production efficiency's technical problem.

In order to achieve the above object, the utility model provides an integral bay window centre form includes:

the number of the first splicing modules is multiple;

the second concatenation module, the quantity of second concatenation module is a plurality of, and is a plurality of second concatenation module interval sets up in adjacent two between the first concatenation module, and with adjacent two the first concatenation module is connected, the second concatenation module has and is close to and keeps away from the first concatenation position and the second concatenation position of first concatenation module are a plurality of first concatenation module and a plurality of the second concatenation module encloses to close and forms the interior die face of pouring the space to and the second concatenation module

The adjusting mechanism is connected with the first splicing modules and used for driving the first splicing modules to move towards or away from the adjusting mechanism.

In an embodiment, when the second splicing module is located at the first splicing position, the outer side surface of the second splicing module is aligned with the outer side surface of the first splicing module, and when the second splicing module is located at the second splicing position, the second splicing module is far away from the first splicing module, and a fit gap is formed between every two adjacent first splicing modules.

In an embodiment, the first splicing module and the two ends connected with the second splicing module are provided with fasteners, the two ends of the second splicing module are respectively provided with adjusting holes, and the fasteners are movably arranged in the adjusting holes in a penetrating mode so as to drive the second splicing module to move between the first splicing position and the second splicing position.

In an embodiment, the second splicing module has a protruding portion on one side away from the adjusting mechanism, two opposite sides of the protruding portion and the first splicing module are provided with guide inclined planes, the end portion of the first splicing module is provided with a matching inclined plane, and the guide inclined plane is movably abutted to the matching inclined plane so as to embed the second splicing module into the matching gap.

In an embodiment, the adjusting mechanism includes a guide rod and a plurality of connecting members, the guide rod is movable along an axial direction of the casting space, a plurality of first joint points are disposed on an outer peripheral side of the guide rod, a plurality of second joint points are disposed on a side of the first splicing module facing the guide rod, and two ends of the connecting members are respectively hinged to the first joint points and the second joint points.

In one embodiment, when the integral bay window inner die is closed, the connecting pieces are perpendicular to the axial direction of the guide rod and support the first splicing modules together to form the inner die surface; when the integral type bay window inner die is opened, the guide rod is adjusted, and the connecting pieces are mutually closed to form an included angle with the axial line of the guide rod in the length direction so as to drive the first splicing modules to mutually close to enable the inner die face to deform and contract.

In an embodiment, the guide rod is further provided with a sliding block, the first joint point is arranged on the sliding block, the sliding block is sleeved on the guide rod, and the sliding block can slide along the length direction of the guide rod.

In one embodiment, at least two second joint points are arranged on one first splicing module, and the two joint points are arranged on the outer peripheral side of the first splicing module at intervals.

In an embodiment, the number of the first splicing modules is four, the number of the second splicing modules is four, and the four first splicing modules and the four second splicing modules are arranged at intervals to form the inner mold surface with a square structure.

In one embodiment, the second splice module further comprises a handle assembly disposed on a side of the second splice module proximate to the adjustment mechanism.

The utility model also provides a bay window mould, the bay window mould includes as above integral bay window centre form, integral bay window centre form includes first concatenation module, second concatenation module and adjustment mechanism. The number of the first splicing modules is multiple; the quantity of second concatenation module is a plurality of, and is a plurality of second concatenation module interval sets up in adjacent two between the first concatenation module, and with adjacent two first concatenation module is connected, the second concatenation module has and is close to and keeps away from first concatenation position and second concatenation position of first concatenation module, and is a plurality of first concatenation module and a plurality of the second concatenation module encloses to close and forms the interior die face of pouring the space, adjustment mechanism connects a plurality ofly first concatenation module is used for driving first concatenation module is to being close to or keeping away from adjustment mechanism's direction removes.

The integral convex window inner die is divided into a plurality of first splicing modules, a plurality of second splicing modules and an adjusting mechanism, the second splicing modules move between a first splicing position and a second splicing position, so that the two adjacent first splicing modules can be pre-tightened or unfolded, then the adjusting mechanism drives the first splicing modules and the second splicing modules connected with the first splicing modules to move in the direction close to or far away from the adjusting mechanism, and the die assembly and die opening of the integral convex window inner die are completed, so that the first splicing modules, the second splicing modules and the adjusting mechanism can be kept in integral connection during die assembly or die opening, the processes of detaching and installing the inner die one by one are saved, and the aim of rapidly detaching and installing the integral convex window inner die is fulfilled, the production efficiency of the bay window is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be 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 of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic structural view of the integral type bay window inner mold according to the present invention when the second splicing mechanism is at the first splicing position;

FIG. 2 is a cross-sectional view taken at A-A of FIG. 1;

fig. 3 is a schematic structural view of the integral type bay window inner mold when the second splicing mechanism is at the second splicing position;

FIG. 4 is an enlarged view at A in FIG. 3;

FIG. 5 is a cross-sectional view taken at B-B of FIG. 3;

FIG. 6 is a schematic structural diagram of the first splice module of FIG. 3;

FIG. 7 is a schematic structural diagram of the second splice module of FIG. 3;

FIG. 8 is a schematic view of the structure of the guide post in FIG. 3;

fig. 9 is a schematic structural view of the connector of fig. 3.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)
				10	Integral convex window internal mold	122a	Guide ramp
11	First splicing module	123	Handle assembly
				111	Fastening piece	13	Adjusting mechanism
112	Matching inclined plane	131	Guide rod
				113	Second joint point	131a	First joint point
12	Second splice module	132	Connecting piece
				121	Adjusting hole	14	Inner mould surface
122	Raised part	15	Fitting clearance

The objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

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 in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that, if directional indications (such as upper, lower, left, right, front and rear … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description relating to "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, if appearing throughout the text, "and/or" is meant to include three juxtaposed aspects, taking "A and/or B" as an example, including either the A aspect, or the B aspect, or both A and B satisfied aspects. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

The utility model provides an integral bay window centre form.

In the embodiment of the present invention, as shown in fig. 1 to 5, the integral bay window inner mold 10 includes a first splicing module 11, a second splicing module 12, and an adjusting mechanism 13. The number of the first splicing modules 11 is multiple; the quantity of second concatenation module 12 is a plurality of, and is a plurality of second concatenation module 12 interval sets up in adjacent two between the first concatenation module 11, and with adjacent two first concatenation module 11 is connected, second concatenation module 12 has and is close to and keeps away from the first concatenation position and the second concatenation position of first concatenation module 11 are a plurality of first concatenation module 11 and a plurality of second concatenation module 12 encloses and closes the interior die face 14 that forms the space of pouring, adjustment mechanism 13 connects a plurality ofly first concatenation module 11 is used for driving first concatenation module 11 is to being close to or keeping away from adjustment mechanism 13's direction removes.

Particularly, in the embodiment of the utility model, integral bay window centre form 10 includes first concatenation module 11, first concatenation module 11 is by channel-section steel, angle steel etc. utilize welded forming's steel structure spare, there is the component that is used for forming to pour the space inner membrane face on the 11 periphery sides of first concatenation module, in this embodiment, first concatenation module 11 is because two sets of angle steel or channel-section steel form certain contained angle each other and set up the strengthening rib welding formation in two sets of angle steel or channel-section steel. The first splicing module 11 is disposed in a substantially triangular shape, but in other embodiments, the first splicing module 11 may also be disposed in a square or polygonal shape, and is not limited herein. Other embodiments may be practiced with reference to this embodiment. Optionally, the integral bay window inner mold 10 may include 4, 6, 8, or 10 of the first splicing modules 11, which may be arranged according to the inner contour of a specific bay window and the process requirements, and is not limited herein.

The embodiment of the utility model provides an in, integral bay window centre form 10 still includes second concatenation module 12, second concatenation module 12 is by channel-section steel, angle steel and bracket etc. utilize the steel structure spare of mutual weld forming, there is the component that is used for forming the space inner membrane face on the second concatenation module 12 periphery side, and is through a plurality of first concatenation module 11's lateral surface with the lateral surface of second concatenation module 12 is connected to form the interior die face 14 that is used for pouring the space of bay window. In this application, a plurality of second concatenation module 12 and a plurality of arrange at an interval each other between the first concatenation module 11 to form the inner circle shape of bay window, second concatenation module 12 and adjacent two swing joint between the first concatenation module 11. Thus, the second stitching module 12 has a first stitching position and a second stitching position with respect to the first stitching module 11. The two splicing modules repeatedly move on the first splicing position and the second splicing position, and can be locked manually or locked by an instrument, and the method is not particularly limited. Specifically, the first splicing module 11 and the second splicing module 12 may be implemented in the form of screws and nuts, and of course, in other embodiments, the first splicing module may be hydraulic or pneumatic, and is not limited in this respect. Alternatively, the integral bay window inner mold 10 may include 4, 6, 8, 10, or the like of the first splicing modules, and may be configured according to the inner contour and the process requirements of a specific bay window and the number of the first splicing modules 11, which is not limited herein.

The embodiment of the utility model provides an in, integral bay window centre form 10 still includes adjustment mechanism 13, first concatenation module 11 with 12 weeks of second concatenation module are located adjustment mechanism 13's periphery side, adjustment mechanism 13 is with a plurality of first concatenation module 11 rotates to be connected to make under the drive of outside mechanism, adjustment mechanism 13 can drive first concatenation module 11 is to being close to or keeping away from adjustment mechanism 13's direction removes. The second splicing module 12 is connected to the adjusting mechanism 13 through the two adjacent first splicing modules 11. So that the adjusting mechanism 13 drives the first splicing module 11 to move towards or away from the adjusting mechanism 13, and indirectly drives the second splicing module 12 to move towards or away from the adjusting mechanism 13, thereby completing the mold closing and opening of the integral bay window inner film. Meanwhile, the first splicing module 11, the second splicing module 12 and the adjusting mechanism 13 are integrally connected during die assembly or die disassembly, so that the integral type bay window inner die 10 is rapidly disassembled and assembled, and the production efficiency of the bay window is improved.

The utility model discloses integral bay window centre form 10 includes first concatenation module 11, second concatenation module 12 and adjustment mechanism 13. The number of the first splicing modules 11 is multiple; the quantity of second concatenation module 12 is a plurality of, and is a plurality of second concatenation module 12 interval sets up in adjacent two between the first concatenation module 11, and with adjacent two first concatenation module 11 is connected, second concatenation module 12 has and is close to and keeps away from the first concatenation position and the second concatenation position of first concatenation module 11 are a plurality of first concatenation module 11 and a plurality of second concatenation module 12 encloses and closes the interior die face 14 that forms the space of pouring, adjustment mechanism 13 connects a plurality ofly first concatenation module 11 is used for driving first concatenation module 11 is to being close to or keeping away from adjustment mechanism 13's direction removes. The integral convex window inner die is divided into a plurality of first splicing modules 11, a plurality of second splicing modules 12 and an adjusting mechanism 13, the second splicing modules 12 move between a first splicing position and a second splicing position, so that the two adjacent first splicing modules 11 can be pre-tightened or opened, then the adjusting mechanism 13 drives the first splicing modules 11 and the second splicing modules 12 connected with the first splicing modules 11 to move in the direction close to or far away from the adjusting mechanism 13, and the die assembly and die opening of the integral convex window inner die 10 are completed, so that the first splicing modules 11, the second splicing modules 12 and the adjusting mechanism 13 can be kept in integral connection during die assembly or die opening, the processes of detaching and installing the inner die one by one are saved, and the purpose of rapidly detaching and installing the integral convex window inner die 10 is achieved, the production efficiency of the bay window is improved.

Referring to fig. 1 to 5, in an embodiment, when the second splicing module 12 is located at the first splicing position, an outer side surface of the second splicing module 12 is aligned with an outer side surface of the first splicing module 11, and when the second splicing module 12 is located at the second splicing position, the second splicing module 12 is away from the first splicing module 11, and a fitting gap 15 is formed between two adjacent first splicing modules 11. It can be understood that, in the present embodiment, when the second splicing module 12 is located at the first splicing position, the outer side surface of the second splicing module 12 is butted against the outer side surface of the first splicing module 11, so as to form the inner mold surface 14 of the casting space, that is, the mold assembly of the integrated bay window inner mold 10 is completed. When the second splicing module 12 is located at the second splicing position, the second splicing module 12 is far away from the first splicing module 11 and faces the adjusting mechanism 13, so that a fit gap 15 is generated between two adjacent first splicing modules 11, and the fit gap 15 can prevent the two adjacent first splicing modules 11 from interfering when the adjusting mechanism 13 drives the two adjacent first splicing modules 11 to be inward, so that the adjusting mechanism 13 is away from the first splicing module 11 and the second splicing module 12, and the die sinking of the integral bay window inner die 10 is completed. Therefore, the friction between the integral type bay window inner die 10 and the inner surface of the bay window component during die opening can be reduced, and the production quality of the integral type bay window inner die 10 is improved. Since the outer side surfaces of the first splicing module 11 and the second splicing module 12 have adhesive force and friction force with concrete when the bay window is formed, the integrity of the bay window can be damaged if the bay window is directly pulled upwards during mold opening. And this application is through inciting somebody to action second concatenation module 12 is removed to second concatenation position by first concatenation position, gives first concatenation module 11 reserves fit clearance 15, then inwards draws in first concatenation module 11, again by adjustment mechanism 13 drives first concatenation module 11 with thereby second concatenation module 12 removes and accomplishes the die sinking to the bay window, only need overcome promptly when the die sinking first concatenation module 11 with the lateral surface of second concatenation module 12 is in have the adhesion stress between the bay window during the shaping and the concrete, the outward appearance of the protruding window spare behind the die sinking is complete to the problem that the bay window collapses the limit easily when solving the die sinking.

Referring to fig. 3 to 7, in an embodiment, fasteners 111 are disposed at two ends of the first splicing module 11 connected to the second splicing module 12, adjusting holes 121 are disposed at two ends of the second splicing module 12, respectively, and the fasteners 111 movably penetrate through the adjusting holes 121 to drive the second splicing module 12 to move between the first splicing position and the second splicing position. In order to realize that the second splicing module 12 can move between the first splicing position and the second splicing position, it is understood that the fastening member 111 can be fixedly connected with both ends of the first splicing member by welding or the like, or can be detachably connected through a fixing hole. Adjusting holes 121 are formed in two ends of the second splicing module 12, the adjusting holes 121 are long holes, the adjusting holes 121 extend towards the directions of the two adjacent first splicing modules 11, the second splicing module 12 can be locked between the fastening piece 111 and the adjusting holes 121 in a matching mode through a matching gap 15 between the two adjacent first splicing modules 11 to complete die assembly, the second splicing can be moved to a second splicing position through matching between the fastening piece 111 and the adjusting holes 121, and the first splicing modules 11 are enabled to have the matching gap 15, so that the first splicing modules 11 move towards the adjusting mechanism 13. Of course, in other embodiments, the second splicing module 12 can be moved between the first splicing position and the second splicing position by a hydraulic mechanism or a pneumatic mechanism. And is not particularly limited herein.

Referring to fig. 4, in an embodiment, the second splice module 12 has a protruding portion 122 on a side away from the adjusting mechanism 13, two sides of the protruding portion 122 opposite to the first splice module 11 are provided with guiding inclined surfaces 122a, an end of the first splice module 11 is provided with a matching inclined surface 112, and the guiding inclined surfaces 122a are movably abutted to the matching inclined surfaces 112 so as to embed the second splice module 12 into the matching gap 15. In order to facilitate the insertion of the second splice module 12 into the fitting gap 15 of two adjacent first splice modules 11 during the closing of the mold, the application provides that the second module is provided with a protrusion on the side facing away from the adjustment mechanism 13, the portion to be inserted into the fitting gap 15 is set as a protrusion 122, the protrusion 122 is trapezoidal, two sides of the protrusion 122 are provided with guiding inclined planes 122a, two adjacent ends of the first splicing modules 11 are provided with fitting inclined planes 112, when the second splice module 12 is fitted into the fitting gap 15, the guide slope 122a and the fitting slope 112 abut against each other, so as to guide the second splicing module 12, improve the matching speed between the first splicing module 11 and the second splicing module 12, further improving the speed of dismounting the integral bay window inner mold 10 and improving the production efficiency of the bay window.

Referring to fig. 3 to 9, in an embodiment, the adjusting mechanism 13 includes a guide rod 131 and a plurality of connecting members 132, the guide rod 131 is movable along an axial direction of the casting space, a plurality of first joint points 131a are disposed on an outer peripheral side of the guide rod 131, a plurality of second joint points 113 are disposed on a side of the first splice module 11 facing the guide rod 131, and two ends of the connecting members 132 are respectively hinged to the first joint points 131a and the second joint points 113. The connection between the first splicing module 11 and the guide rod 131 is completed through the connecting piece 132, and then the rotating connection between the connecting piece 132 and the guide rod 131 and the first splicing module 11 is realized through the first joint point 131a and the second joint point 113, so that the first splicing module 11 is supported during mold closing and driven to contract towards the guide column during mold opening, and the action performance of the adjusting mechanism 13 is improved.

Specifically, when the integral bay window inner mold 10 is closed, the plurality of connecting pieces 132 are arranged perpendicular to the axial direction of the guide rods 131, and jointly support the plurality of first splicing modules 11 to form the inner mold surface 14; when the integral bay window inner die 10 is opened, the guide rod 131 is adjusted, and the plurality of connecting pieces 132 mutually approach to form an included angle with the axis of the guide rod 131 in the length direction, so as to drive the first splicing modules 11 to mutually approach to deform and contract the inner die surface 14.

In an embodiment, the guide rod 131 is further provided with a sliding block, the first joint point 131a is disposed on the sliding block, the sliding block is sleeved on the guide rod 131, and the sliding block can slide along a length direction of the guide rod 131. It can be understood that, in order to further improve the speed of opening the die of the integral bay window inner die 10, the present application may further include sleeving a slider on the outer periphery of the guide rod 131, and setting a first joint point 131a on the slider to connect with the connecting member 132, and then driving the slider to move along the length direction of the guide rod 131 through a driving mechanism, so as to reduce the use of an external component to drive the adjusting mechanism 13 to bring the adjusting mechanism to the first splicing module 11 and the second splicing module 12, and improve the speed of opening the die of the integral bay window inner die 10, thereby improving the production efficiency of the bay window.

Referring to fig. 1 to 5, in an embodiment, at least two second joint points 113 are disposed on one first splicing module 11, and the two joint points are disposed on the outer circumferential side of the first splicing module 11 at intervals. Optionally, 2, 3, 4, 5, 6, 7, 8, 9, 10, etc. of the second joint points 113 may be arranged on one of the first splicing modules 11, and the number of the second joint points 113 arranged on one of the first splicing modules 11 may be set according to the size of the first splicing module 11 and the strength of the connecting member 132, and may be set as needed, which is not limited in this application. This application takes one set up four on the first concatenation module 11 second joint point 113 explains as an example, four second joint point 113 follows the orientation of first concatenation piece the two bisymmetry intervals of lateral surface of deriving set up to the guide pillar passes through the even drive of connecting piece 132 first concatenation module 11 removes, prevents that the single-point atress is too big, causes structural damage, improves the life of integral bay window centre form 10.

Referring to fig. 1 and 3, in an embodiment, the number of the first splicing modules 11 is four, the number of the second splicing modules 12 is four, and the four inner mold surfaces 14 are arranged at intervals between the four first splicing modules 11 and the four second splicing modules 12 to form a square structure. It is understood that the number of the first splicing modules 11 and the second splicing modules 12 can be set according to the shape of the inner side surface of the bay window member and the process requirements, and is not limited herein.

Referring to fig. 3 and 7, in one embodiment, the second splice module 12 further includes a handle assembly 123, the handle assembly 123 being disposed on a side of the second splice module 12 adjacent to the adjustment mechanism 13. It is understood that the handle assembly 123 is disposed on the side of the second splice module 12 close to the adjusting mechanism 13 for the convenience of the operator pulling or prying the second splice module 12 when the second splice module 12 is moved from the first splice position to the second splice position, and the form of the handle assembly 123 can be set as required without any particular limitation, and the handle assembly 123 and the second splice module 12 are connected in a hinged manner in this embodiment to reduce the volume of the second splice module 12. Other embodiments may be practiced with reference to this embodiment.

The utility model also provides a bay window mould, this bay window mould include external mold, base subassembly, support frock and integral bay window centre form 10, and the concrete structure of this integral bay window centre form 10 refers to above-mentioned embodiment, because this bay window mould has adopted the whole technical scheme of above-mentioned all embodiments, consequently has all beneficial effects that the technical scheme of above-mentioned embodiment brought at least, and the repeated description is no longer given here.

Specifically, the base assembly serves as a foundation support and is used for supporting and installing the integral type bay window inner mold 10 and the integral type bay window outer mold, and a pouring space is defined by the base assembly and the integral type bay window inner mold 10 and the integral type bay window outer mold, so that the bay window can be conveniently poured and formed in the pouring space. In this embodiment, the overmold may include a plurality of outer mold plates, each of which may be rotatably coupled to the base assembly. When the mold is required to be opened, the outer templates are rotated to expose the convex window, so that the mold opening operation is simple and easy. When the die is required to be closed, the outer templates are rotated to be spliced to serve as the wall surface of the pouring space. When the outer formworks are combined, in order to avoid slurry leakage caused by rotation of the outer formworks relative to the base assembly in a pouring process, two adjacent outer formworks can be detachably connected together, for example, fastened through fastening bolts. When the mold is required to be opened, the external mold can be opened only by firstly dismounting the fastening bolt and then rotating the external mold plate relative to the base component, which is more convenient.

The above is only the optional embodiment of the present invention, and not the scope of the present invention is limited thereby, all the equivalent structure changes made by the contents of the specification and the drawings are utilized under the inventive concept of the present invention, or the direct/indirect application in other related technical fields is included in the patent protection scope of the present invention.

Claims (11)

1. An integral bay window internal mold, comprising:

the number of the first splicing modules is multiple;

the second concatenation module, the quantity of second concatenation module is a plurality of, and is a plurality of second concatenation module interval sets up in adjacent two between the first concatenation module, and with adjacent two the first concatenation module is connected, the second concatenation module has and is close to and keeps away from the first concatenation position and the second concatenation position of first concatenation module are a plurality of first concatenation module and a plurality of the second concatenation module encloses to close and forms the interior die face of pouring the space to and the second concatenation module

The adjusting mechanism is connected with the first splicing modules and used for driving the first splicing modules to move towards or away from the adjusting mechanism.

2. The integral bay window inner mold of claim 1, wherein when the second splice module is in the first splice position, an outer side of the second splice module is aligned with an outer side of the first splice module, and when the second splice module is in the second splice position, the second splice module is away from the first splice module, and a fit gap is formed between two adjacent first splice modules.

3. The integral bay window inner mold of claim 2, wherein fasteners are disposed at two ends of the first splicing module connected to the second splicing module, adjusting holes are disposed at two ends of the second splicing module, and the fasteners are movably disposed through the adjusting holes to drive the second splicing module to move between the first splicing position and the second splicing position.

4. The integral bay window inner mold of claim 3, wherein the second splice module has a protrusion on a side away from the adjustment mechanism, the protrusion has guide slopes on two sides opposite to the first splice module, the end of the first splice module has a mating slope, and the guide slopes movably abut against the mating slopes to insert the second splice module into the mating gap.

5. The integral type bay window inner mold according to claim 4, wherein the adjusting mechanism comprises a guide rod and a plurality of connecting members, the guide rod is movable along an axial direction of the casting space, a plurality of first joint points are provided on an outer circumferential side of the guide rod, a plurality of second joint points are provided on a side of the first splicing module facing the guide rod, and two ends of the connecting members are respectively hinged to the first joint points and the second joint points.

6. The integrated bay window inner mold of claim 5, wherein when the integrated bay window inner mold is closed, the plurality of connecting pieces are arranged perpendicular to the axial direction of the guide rod and jointly support the plurality of first splice modules to form the inner mold surface; when the integral type bay window inner die is opened, the guide rod is adjusted, and the connecting pieces are mutually closed to form an included angle with the axial line of the guide rod in the length direction so as to drive the first splicing modules to mutually close to enable the inner die face to deform and contract.

7. The integral type bay window internal mold of claim 5, wherein the guide rod is further provided with a slide block, the first joint point is arranged on the slide block, the slide block is sleeved on the guide rod, and the slide block can slide along the length direction of the guide rod.

8. The integral bay window inner mold of claim 5, wherein at least two of said second joints are provided on one of said first splice modules, said two second joints being spaced apart on the circumferential side of said first splice module.

9. The integral bay window inner mold of claim 1, wherein the number of the first splice modules is four, the number of the second splice modules is four, and four of the first splice modules and four of the second splice modules are spaced apart from each other to form the inner mold surface in a square configuration.

10. The integral bay window inner mold of claim 1, wherein the second splice module further comprises a handle assembly disposed on a side of the second splice module proximate the adjustment mechanism.

11. A bay window mould comprising an integral bay window inner mould as claimed in any one of claims 1 to 10.

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