CN218019158U - Part mould - Google Patents

Abstract

The utility model relates to the technical field of iron tower processing, in particular to a part mould, which comprises a bottom plate and a plurality of coamings hinged at the edge of the bottom plate, wherein the part mould has a pouring state and a demoulding state; in a pouring state, adjacent enclosing plates and the bottom plate are connected in a sealing mode to form a containing cavity for pouring an assembled part, the assembled part can form an iron tower foundation, and a locking mechanism is arranged between the two enclosing plates and used for locking a part mold in a pouring state; in the demoulding state, the locking mechanism releases the locking of the coaming, so that the coaming can rotate and unfold relative to the bottom plate. Through rotating the relative bottom plate of a plurality of bounding walls to the sealed chamber that holds that is used for pouring the equipment part who constitutes iron tower basis that forms of mutual butt, rethread locking mechanical system locks, can relieve locking mechanical system's locking after the equipment part pouring finishes and the induration, the drawing of patterns of being convenient for, consequently the part die design of this application is simple, and the debugging time is short, and pouring efficiency is high.

Description

Part mould

Technical Field

The application relates to the technical field of iron tower processing, in particular to a part mold.

Background

In order to fix the iron tower in the earth ground, the iron tower foundation needs to be pre-buried in the ground, and the steel bars are conveniently welded on the iron tower foundation to form the iron tower body. The iron tower foundation is generally formed by pouring reinforced concrete in a mould, and because the installation precision of the iron tower foundation is higher, and each project is basically in a remote mountain forest, the iron tower foundation generally has no mould carrying condition and pouring condition. Therefore, prefabricated foundations are currently used and transported to the construction site for installation. Prefabricated foundations are simply the foundations that are broken down into several pieces and then assembled at the factory and transported to the tower site. The mode can improve the labor condition, plays a role in accelerating the line progress, and is particularly suitable for construction in mountainous areas, hilly areas and winter.

However, the prefabricated foundation has high requirement on the casting accuracy of the casting mold, which results in complex mold structure design and high cost. And the mold is required to be demolded after each pouring, and then the mold is reassembled to pour again, so that the debugging time is long and the pouring efficiency is low.

SUMMERY OF THE UTILITY MODEL

The embodiment of the utility model provides an aim at: the utility model provides a part mould, it can solve among the prior art problem that casting mold structural design is complicated, with high costs and pouring inefficiency.

In order to achieve the purpose, the following technical scheme is adopted in the application:

providing a part mould, which comprises a bottom plate and a plurality of enclosing plates hinged to the edge of the bottom plate, wherein the part mould has a pouring state and a demoulding state;

in a pouring state, the adjacent enclosing plates and the bottom plate are connected in a sealing mode to form a containing cavity for pouring an assembled part, the assembled part can form an iron tower foundation, and a locking mechanism is arranged between the two adjacent enclosing plates and used for locking the part mold in a pouring state;

in the demoulding state, the locking mechanism releases the locking of the coaming, so that the coaming can rotate and unfold relative to the bottom plate.

As a preferable aspect of the part mold, the locking mechanism includes:

the locking seat is fixedly arranged on one coaming;

the locking block is fixedly arranged on the other coaming;

one end of the connecting rod is hinged to the locking seat;

the bent rod is provided with a first end and a second end which are oppositely arranged, a groove is concavely arranged between the first end and the second end, and the first end is hinged with the other end of the connecting rod;

the locking rod is provided with a connecting end and a locking end, the connecting end is fixedly connected with the second end, and the locking end is detachably connected with the locking block.

As a preferable mode of the part mold, the locking mechanism further includes an adjustment module, the adjustment module is disposed between the second end and the connection end, and the adjustment module is configured to adjust a relative distance between the second end and the connection end.

As a preferred scheme of the part mold, the second end is provided with an adjusting hole, the adjusting module comprises an adjusting nut and a threaded portion arranged on the connecting end, the threaded portion can pass through the inner portion of the adjusting hole, and the adjusting nut is in threaded connection with the threaded portion and located at two ends of the adjusting hole.

As a preferable scheme of the part mold, the locking block is concavely provided with a locking groove, the locking end is extendedly provided with a locking portion, and the locking portion is detachably connected with the locking groove.

As a preferable scheme of the component mold, the enclosing plate is provided with a through hole, and the component mold further comprises:

and the taper pin is detachably arranged in the through hole, so that the assembling part forms a connecting hole for accommodating a connecting screw rod.

As a preferable scheme of the part mold, a projection is convexly arranged on a wall surface where the through hole is located, and the projection corresponds to a position where the connecting plate is arranged on the assembling part.

As a preferable mode of the component mold, the top section width of the bump is smaller than the bottom section width of the bump, so that the side wall of the bump forms a slope.

As a preferable mode of the part mold, the connection plate is provided corresponding to a top section of the projection.

As a preferable scheme of the part mold, a positioning block is arranged on an inner wall of the accommodating cavity, and the positioning block corresponds to a splicing position of the assembly part.

The beneficial effect of this application does:

a plurality of coamings are hinged to the edge of the bottom plate, the coamings can be rotated to be mutually abutted and sealed relative to the bottom plate, and therefore a containing cavity for pouring assembly parts forming an iron tower foundation is formed. The part mould of this application has pouring state and drawing of patterns state, and sealing connection between the bounding wall that is adjacent under the pouring state and between bounding wall and the bottom plate. Meanwhile, a locking mechanism is arranged between the two enclosing plates, and the part mould can be locked to be in a pouring state through the locking mechanism, so that the assembled parts are kept between the enclosing plates and the bottom plate can be stably arranged when the assembled parts are poured, and the risk of deformation of the assembled iron tower foundation is reduced.

In addition, after the assembly part is poured and hardened, the locking mechanism can be unlocked, and the pouring mold can be returned to the demolding state. Because the coaming is hinged with the bottom plate, the coaming is connected with the bottom plate, the coaming can be unfolded in a rotating way relative to the bottom plate, and meanwhile, the coaming can be conveniently detached from the assembly part. Before the next pouring, the adjacent enclosing plates can be continuously abutted and locked to the pouring state through the locking mechanism, and the assembled part can be formed by repeated pouring.

Therefore, the part mold is simple in design, low in cost, short in debugging time and high in pouring efficiency.

Drawings

The present application will be described in further detail below with reference to the accompanying drawings and examples.

Fig. 1 is a schematic structural diagram of unlocking a part mold according to an embodiment of the present application.

Fig. 2 is a schematic structural diagram of a locking mechanism according to an embodiment of the present application.

Fig. 3 is a schematic structural diagram of a part mold lock according to an embodiment of the present application.

Fig. 4 is a schematic structural view of a part mold lock according to another embodiment of the present application.

In the figure:

1. a base plate; 2. enclosing plates; 21. a through hole; 22. a bump;

3. a locking mechanism; 31. a locking seat; 32. a locking block; 321. locking the groove; 33. a connecting rod;

34. a curved bar; 341. a first end; 342. a second end; 343. a groove;

35. a locking lever; 351. a connecting end; 352. a locking end; 3521. a locking portion;

36. an adjustment module; 361. adjusting the nut; 362. a threaded portion; 4. and (5) positioning the blocks.

Detailed Description

In order to make the technical problems solved, technical solutions adopted, and technical effects achieved by the present application clearer, the following describes technical solutions of embodiments of the present application in further detail, and it is obvious that the described embodiments are only a part of embodiments of the present application, but not all 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 application.

In the description of the present application, unless expressly stated or limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly and may for example be fixedly connected, detachably connected, or integral to one another; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In this application, unless expressly stated or limited otherwise, the recitation of a first feature "on" or "under" a second feature may include the recitation of the first and second features being in direct contact, and may also include the recitation of the first and second features not being in direct contact, but being in contact with another feature between them. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

As shown in fig. 1, the embodiment provides a component mold, which includes a bottom plate 1 and a plurality of enclosing plates 2 hinged to the edge of the bottom plate 1, wherein the component mold has a pouring state and a demolding state;

in a pouring state, adjacent enclosing plates 2 and the bottom plate 1 are connected in a sealing mode to form a containing cavity for pouring an assembled part, the assembled part can form an iron tower foundation, a locking mechanism 3 is arranged between the two enclosing plates 2, and the locking mechanism 3 is used for locking a part mould in a pouring state;

in the mold-released state, the locking mechanism 3 unlocks the apron 2 so that the apron 2 can be rotated and unfolded with respect to the base plate 1.

This application is provided with a plurality of bounding walls 2 through the edge hinge at bottom plate 1, can rotate a plurality of 2 relative bottom plates of bounding walls 1 to mutual butt through articulated setting and seal to form the chamber that holds that is used for the pouring to constitute the equipment part on iron tower basis. The number of the enclosing plates 2 can be set according to the outline of the assembly component, for example, if the assembly component is a square structure, the number of the enclosing plates 2 can be four, forming four sides of the square structure. Alternatively, the enclosure 2 and the side of the base plate 1 forming the receiving cavity may be shaped in relation to the shape of the assembled components so that the required shape of the assembled components may be cast through the receiving cavity. In one embodiment, the mutually abutting seal means that the surrounding plate 2 and the edge of the bottom plate 1 abut against each other to form a sealed cavity. The part mold of the present application has a pouring state and a demolding state, wherein the pouring state is a state in which a pouring object such as concrete can be poured after the shroud plate 2 and the bottom plate 1 are fixedly disposed. The enclosing plates 2 adjacent to each other in the pouring state and the bottom plate 1 and the enclosing plates 2 hinged with the edges of the bottom plate 1 are connected in a sealing mode (namely, mutually abutted and sealed). In one embodiment, a locking mechanism 3 is arranged between two enclosing plates 2, the component mould can be locked to be in a pouring state through the locking mechanism 3, namely in the pouring state, the assembled components are kept to be stably arranged between the enclosing plates 2 and the bottom plate 1 during pouring through the locking mechanism 3, and the risk of deformation of the assembled iron tower foundation is reduced. It is understood that the number of the locking mechanisms 3 can be one or more, and the two enclosing plates 2 provided with the same locking mechanism 3 can be adjacent enclosing plates or non-adjacent enclosing plates, when the two enclosing plates 2 are not adjacent, the two enclosing plates 2 and at least one enclosing plate between the two enclosing plates 2 can be locked through the locking mechanisms 3. It should be noted that at least one enclosing plate between two enclosing plates 2 refers to at least one enclosing plate which is fixed by the two enclosing plates 2 where the locking mechanism 3 is located when the locking mechanism 3 is locked.

In addition, after the assembled parts are completely poured and hardened, the locking mechanism 3 can be unlocked, and the pouring mold can be returned to the demolding state. The demoulding state means that the casting is hardened to form the assembly part, at the moment, the coaming 2 can be opened, so that the coaming 2 can rotate relative to the bottom plate 1, and the assembly part can be separated from the coaming 2 and the bottom plate 1. It will be appreciated that the locking mechanism 3 comprises a locked state in which the component mould corresponds to the casting state and an unlocked state in which the component mould corresponds to the demoulding state, and that after the locking of the closure 2 by the locking mechanism 3 is released, the closure 2 can be rotated relative to the base plate 1 to open the closure 2. Because bounding wall 2 is articulated with bottom plate 1 for keep being connected between bounding wall 2 and the bottom plate 1, bounding wall 2 can rotate the expansion relative to bottom plate 1, also is convenient for bounding wall 2 to dismantle from the equipment part simultaneously. Before the next pouring, the adjacent enclosing plates 2 can be continuously abutted against each other and locked in a pouring state through the locking mechanism 3, and the pouring can be repeated for multiple times to form the assembled part.

Therefore, the part mold is simple in design, low in cost, short in debugging time and high in pouring efficiency. Referring to fig. 2, specifically, the lock mechanism 3 includes a lock base 31, a lock block 32, a connecting rod 33, a curved rod 34, and a lock lever 35. Wherein: the locking seat 31 is fixedly arranged on one of the coamings 2; a locking block 32 fixedly arranged on the other coaming 2; a connecting rod 33 having one end hinged to the locking seat 31; a curved rod 34 having a first end 341 and a second end 342 opposite to each other, a groove 343 being concavely formed between the first end 341 and the second end 342, the first end 341 being hinged to the other end of the connecting rod 33; and the locking rod 35 is provided with a connecting end 351 and a locking end 352, wherein the connecting end 351 is fixedly connected with the second end 342, and the locking end 352 is detachably connected with the locking block 32.

Illustratively, the locking seat 31 is fixedly arranged on one enclosing plate 2, and the locking block 32 is fixedly arranged on the other enclosing plate 2, and the two enclosing plates 2 can be regarded as enclosing plates for arranging the locking mechanism 3. The positions of the locking seat 31 and the locking block 32 on the corresponding enclosing plates 2 are not limited in the present, and optionally, the plane of one enclosing plate 2 where the locking seat 31 is arranged and the plane of the other enclosing plate where the locking block 32 is arranged are the same plane, and in some cases, in combination with the specific shape of the locking mechanism 3, the locking block 32 and the locking seat 31 may also be arranged on enclosing plates in different planes. It will be appreciated that the two enclosures 2 may be arranged adjacent to each other or spaced apart. Alternatively, two enclosing plates 2 separated by one enclosing plate 2 are respectively provided with a locking seat 31 and a locking block 32, and three enclosing plates 2 can be simultaneously fixed through one locking mechanism. Alternatively, a plurality of locking mechanisms 3 (for example, a locking block 32 or a locking seat 31 of one locking mechanism 3 is provided, and a locking block 32 or a locking seat 31 of another locking mechanism 3 is provided) are provided on the same enclosure 2, so that the enclosure 2 at different relative positions can be locked by the plurality of locking mechanisms 3.

One end of the connecting rod 33 is hinged to the locking seat 31, for example, to the middle of the locking seat 31, or to the end of the locking seat 31 near the curved rod 34, so that the connecting rod 33 can rotate relative to the locking seat 31. And the curved rod 34 has a first end 341 and a second end 342 which are oppositely arranged, a groove 343 is concavely arranged between the first end 341 and the second end 342, and the first end 341 is hinged with the other end of the connecting rod 33, so that the curved rod 34 can rotate relative to the locking seat 31 along with the connecting rod 33, and the groove 343 is driven to be close to the surface of the locking seat 31. Meanwhile, the locking lever 35 has a connecting end 351 and a locking end 352, the connecting end 351 is fixedly connected with the second end 342, and the locking end 352 is detachably connected with the locking block 32. At this time, since the locking end 352 is detachably connected to the locking block 32, after the locking end 352 of the locking rod 35 is rotatably clamped to the locking block 32, the curved rod 34 and the connecting rod 33 fixedly connected to the locking rod 35 are driven to rotate relative to the locking seat 31, and as the groove 343 approaches the locking seat 31, the relative distance between the locking seat 31 and the locking block 32 is gradually shortened until the groove 343 of the curved rod 34 approaches the locking seat 31 to the maximum extent, and the two ends of the locking rod 35 tighten the locking seat 31 and the locking block 32 to complete the locking. In this embodiment, by deepening the groove 343, the rotation amplitude of the curved rod 34 relative to the locking seat 31 can be increased, and the effect of increasing the movement amplitude of the locking rod 35 and the relative movement distance between the locking seat 31 and the locking block 32 is achieved. The locking mechanism 3 of the present embodiment can lock two neighboring enclosures 2, and also can lock three neighboring enclosures 2, and keep the component mold in a casting state.

Alternatively, referring to fig. 3, the locking seat 31 and the locking block 32 may be provided on the edges of two different enclosures 2 sandwiching the other enclosure 2 between the two different enclosures 2 so that the locking seat 31 and the locking block 32 can lock three enclosures 2 simultaneously. The fixing manner of the locking seat 31 and the locking block 32 to the coaming 2 may be welding fixing, integral setting, screw connection or adhesion, and this embodiment is not limited in particular.

When the locking mechanism 3 needs to be disassembled, the curved rod 34 and the connecting rod 33 are driven to rotate relative to the locking seat 31, the locking block 32 can be driven to move close to the locking seat 35, and the locking end 352 gradually gets away from the locking block 32, so that the locking end 352 of the locking rod 35 can be separated from the locking block 32, the locked coaming 2 is unlocked, and demolding is facilitated.

Further, with continued reference to fig. 2, the locking mechanism 3 also includes an adjustment module 36. The adjusting module 36 is disposed between the second end 342 and the connecting end 351, and the adjusting module 36 is used for adjusting the relative distance between the second end 342 and the connecting end 351. The length of the locking lever 35 can be adjusted according to the relative positions of the locking seat 31 and the locking block 32, thereby adjusting the tightness of the locking mechanism 3. For example, when the distance between the two enclosing plates 2 is long, the locking length of the locking lever 35 can be changed by the adjusting module 36 to match the distance between the two enclosing plates 2. Moreover, when the relative length of the locking rod 35 is changed, the rotatable range of the curved rod 34 relative to the locking seat 31 is increased, so that the groove 343 of the curved rod 34 can completely abut against the locking seat 31, the stability of the locking mechanism 3 during locking can be improved, and the stability of connection between the enclosing plates 2 can be ensured.

For the implementation of the adjusting module 36, specifically, referring to fig. 2, the second end 342 is opened with an adjusting hole, the adjusting module 36 includes an adjusting nut 361 and a threaded portion 362, and the threaded portion 362 is disposed on the connecting end 351. The threaded portion 362 is disposed through the adjusting hole, and the adjusting nut 361 is threaded onto the threaded portion 362 and located at two ends of the adjusting hole. During adjustment, the threaded portion 362 of the connecting end 351 penetrates through the adjusting hole, the adjusting nut 361 is screwed on the threaded portion 362 until the adjusting nut 361 abuts against the adjusting hole, and the adjusting module 36 is kept fixedly connected with the locking rod 35 after adjustment, so that the groove 343 of the retaining curved rod 34 abuts against the locking seat 31 and the locking end 352 of the locking rod 35 is clamped on the locking block 32.

Alternatively, referring to fig. 2, lock block 32 is concavely provided with lock groove 321, and lock end 352 is extendedly provided with lock portion 3521, lock portion 3521 is detachably connected with lock groove 321, wherein the detachable connection mode is not limited at present, such as snapping connection, and can fix the connection between lock portion 3521 and lock groove 321. More preferably, the locking groove 321 may be circular arc-shaped, the locking part 3521 may be cylindrical, and the locking part 3521 may be configured to rotate relative to the locking groove 321, so as to facilitate adjustment of the relative distance of the curved lever 34 with respect to the locking seat 31.

As shown in fig. 3, in particular, the enclosing plate 2 is provided with a through hole 21, and the component mold of the present application further includes a taper pin (not shown in the figure) which is detachably disposed in the through hole 21, so that the assembly component can form a connecting hole for accommodating the connecting screw. The taper pin is a pin with one thin end and the other thick end, the thin end is inserted into the component mould, the thick end is arranged outside the component mould, after the component is assembled after pouring, the taper pin can be directly forced on the thick end to be removed from the component mould, a hole corresponding to the profile of the taper pin is reserved on the assembled component, and compared with the pin with uniform two ends, the taper pin can reduce the pulling resistance. Furthermore, the hole left by the slight pin extraction can be machined to provide a threaded hole for the connecting screw.

Preferably, referring to fig. 1, a protrusion 22 is protruded from a wall surface where the through hole 21 is located, the protrusion 22 corresponds to a position where a connection plate is provided on the assembly member, the connection plate is a connection structure for connecting a plurality of assembly members, and the protrusion 22 is provided with the through hole 21 to fix the connection plate and the assembly member by a bolt. The wall surface where the through hole 21 is located is the inner wall surface of the shroud 2. After the part mould drawing of patterns of this application, the position that corresponds lug 22 on the equipment part is the holding tank, and the holding tank can hold the connecting plate, is about to the connecting plate setting on the holding tank for the connecting plate can be less than or the parallel and level in the surface of equipment part, improves the roughness on the iron tower basis after the equipment.

More preferably, and with reference to fig. 1, the top cross-sectional width of the bump 22 is less than the bottom cross-sectional width of the bump 22, such that the sidewalls of the bump 22 are tapered, again to reduce resistance to demolding of the bump 22 from the assembled component.

In order to further stabilize the position of the connecting plate on the assembly member, the connecting plate is arranged corresponding to the top section of the bump 22 (not shown in the figure), the connecting plate can be correspondingly arranged on the bump 22, and the assembly member is demolded after being poured, so that the connecting plate is kept on the assembly member, namely the connecting plate is pre-embedded on the assembly member and is fixed by hard bonding along with the assembly member.

In addition, referring to fig. 1, the inner wall of the accommodating chamber is provided with a positioning block 4, and the positioning block 4 corresponds to a splicing position of the assembly parts. Set up the constant head tank that can make the equipment part that the pouring was accomplished form corresponding 4 outlines of locating piece after the locating piece 4, and can carry out the butt between constant head tank and the equipment part between a plurality of equipment parts to assemble into iron tower basis, and the constant head tank not only can play the effect of suggestion equipment direction, can also regard as spacing between the equipment part and improve iron tower basis's assembly stability.

Preferably, the positioning block 4 may be disposed at an edge of the surrounding plate 2, or at a corner of the surrounding plate 2, so that the assembled component after being poured can be used as the edge of the iron tower foundation, or as a corner of the iron tower foundation.

Referring to fig. 4, a plate body may be added on the basis of the circumferential plate 2 of the part mold, so as to extend the height of the assembled part, and the upright post of the iron tower foundation may be poured. According to actual needs, the size of the coaming 2 can be changed to form different assembly parts, and the description of this embodiment is omitted.

In the description herein, it is to be understood that the terms "upper," "lower," "left," "right," and the like are used in an orientation or positional relationship merely for convenience in description and simplicity of operation, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the present application. Furthermore, the terms "first" and "second" are used merely for descriptive purposes and are not intended to have any special meaning.

In the description herein, references to the description of "an embodiment," "an example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be appropriately combined to form other embodiments as will be appreciated by those skilled in the art.

The technical principles of the present application have been described above in connection with specific embodiments. The description is made for the purpose of illustrating the principles of the present application and is not to be construed in any way as limiting the scope of the application. Based on the explanations herein, a person skilled in the art will be able to conceive of other embodiments of the present application without inventive effort, which shall fall within the scope of protection of the present application.

Claims (10)

1. The part mould is characterized by comprising a bottom plate (1) and a plurality of enclosing plates (2) hinged to the edge of the bottom plate (1), and the part mould has a pouring state and a demoulding state;

in a pouring state, the adjacent enclosing plates (2) and the bottom plate (1) are connected in a sealing mode to form a containing cavity for pouring an assembled part, the assembled part can form an iron tower foundation, a locking mechanism (3) is arranged between the two enclosing plates (2), and the locking mechanism (3) is used for locking the part mould in the pouring state;

in a demoulding state, the locking mechanism (3) releases the locking of the coaming (2) so that the coaming (2) can rotate and unfold relative to the bottom plate (1).

2. A part mould according to claim 1, characterized in that the locking mechanism (3) comprises:

the locking seat (31) is fixedly arranged on one enclosing plate (2);

the locking block (32) is fixedly arranged on the other enclosing plate (2);

a connecting rod (33) with one end hinged to the locking seat (31);

the crank rod (34) is provided with a first end (341) and a second end (342) which are oppositely arranged, a groove (343) is concavely arranged between the first end (341) and the second end (342), and the first end (341) is hinged with the other end of the connecting rod (33);

a locking lever (35) having a connecting end (351) and a locking end (352), the connecting end (351) being fixedly connected with the second end (342), the locking end (352) being detachably connected with the locking block (32).

3. The part mold of claim 2, wherein the locking mechanism (3) further comprises an adjustment module (36), the adjustment module (36) being disposed between the second end (342) and the connecting end (351), the adjustment module (36) being for adjusting a relative distance of the second end (342) and the connecting end (351).

4. The part mold according to claim 3, wherein the second end (342) is opened with an adjusting hole, the adjusting module (36) comprises an adjusting nut (361) and a threaded portion (362) disposed at the connecting end (351), the threaded portion (362) is disposed through the adjusting hole, and the adjusting nut (361) is threaded onto the threaded portion (362) and located at two ends of the adjusting hole.

5. The component mold of claim 2, wherein the locking piece (32) is concavely provided with a locking groove (321), the locking end (352) is extendedly provided with a locking part (3521), and the locking part (3521) is detachably connected with the locking groove (321).

6. The component mold according to claim 1, characterized in that the shroud (2) is perforated with through holes (21), the component mold further comprising:

and the taper pin is detachably arranged in the through hole (21) so that the assembling part forms a connecting hole for accommodating a connecting screw rod.

7. A part mould according to claim 6, characterised in that the wall where the through hole (21) is located is provided with a protruding block (22) in a protruding manner, which protruding block (22) corresponds to the position where the connection plate is provided on the assembled part.

8. The component mold of claim 7, wherein a top cross-sectional width of the bump (22) is less than a bottom cross-sectional width of the bump (22) such that a sidewall of the bump (22) forms a ramp.

9. A part mould according to claim 7, characterized in that the web is arranged in correspondence with the top section of the bumps (22).

10. Component mould according to claim 1, characterized in that the inner wall of the receiving cavity is provided with positioning blocks (4), which positioning blocks (4) correspond to the splicing positions of the assembled components.

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