CN114174613A

CN114174613A - Aluminum mold panel assembly for building

Info

Publication number: CN114174613A
Application number: CN202080052067.3A
Authority: CN
Inventors: 金炳镐
Original assignee: KUM KANG INDUSTRY CO LTD
Current assignee: KUM KANG INDUSTRY CO LTD
Priority date: 2019-07-26
Filing date: 2020-06-02
Publication date: 2022-03-11
Anticipated expiration: 2040-06-02
Also published as: KR102306314B1; WO2021020712A1; KR20210012779A; CN114174613B

Abstract

The present invention relates to an aluminum mold panel assembly for construction, which includes a first unit panel and a second unit panel having one end portion formed with a reinforcing rib fixed in a state of being closely attached to each other, wherein an insertion groove portion formed by expanding an inner space relative to an open space is formed on one surface of surfaces of the first unit panel and the second unit panel closely attached to each other, and a fixing protrusion portion is provided on the other surface thereof, and a shape of the fixing protrusion portion is deformed by an external force and is pressed and fixed into the insertion groove portion in a state where the fixing protrusion portion is inserted into the insertion groove portion.

Description

Aluminum mold panel assembly for building

Technical Field

The present invention relates to an aluminum mold panel assembly for construction, and more particularly, to an aluminum mold panel assembly for construction in which a pair of unit panels constituting a finished panel can be firmly fixed by pressing.

Background

Building walls of apartments, buildings, general houses, and the like are formed by forming a basic shape using a mold, pouring concrete, and curing. Generally, a mold is a temporary structure that can keep concrete in a prescribed shape and size, prevent moisture required in curing of the concrete from leaking, and prevent external impact and the like from affecting the concrete, and is used until the concrete is cured. The construction of the mould has important influence on the construction process and the result of the concrete and has great influence on the ending engineering, so a great deal of heart blood is spent on the construction of the mould.

The above-described mold is classified into a wood-steel form (wood-steel form) in which plywood is bonded to the entire surface of a general steel frame, and an advanced aluminum form (aluminum form) made of aluminum.

The former European style formwork can be detached and reused after pouring, but the weight is heavy due to a frame formed by thick plywood and steel, and the formwork is difficult to be operated by an operator. Therefore, when the european style formwork is manufactured in a smaller size, the number of connecting works is increased during construction, thereby increasing the construction time and cost.

In addition, an aluminum material mold constructed in the following manner is proposed in korean utility model publication No. 20-0169470, "concrete mold": a plate material having a width half of the size of a plate material to complete one die and a side frame formed vertically from one side end of the plate material are integrally formed by extrusion molding, and the two plate materials are symmetrically welded to construct the aluminum die.

However, the conventional aluminum mold has a structure in which a pair of plate materials are welded to each other, and thus has a problem in that a large number of defective fractions are generated in the welding process.

Further, since the plate is likely to have holes during welding due to the material characteristics of aluminum, it is preferable to minimize the welded portion because the plate is made to have a thickness more than necessary, which becomes a major factor in increasing the die load and the production cost.

Disclosure of Invention

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide an aluminum mold panel assembly for construction that can firmly fix a pair of unit panels constituting a finished panel by pressing.

Further, the present invention provides an aluminum mold panel assembly for construction that can exert a strong fixing force even if a pressure for deforming a fixing protrusion is not completely provided in a process of pressing a pair of unit panels.

The present invention provides an aluminum mold panel assembly for construction, comprising a first unit panel and a second unit panel for constituting a finished panel, wherein reinforcing ribs are formed at one side end of the first unit panel and one side end of the second unit panel, respectively, the one side ends are fixed in a state of being closely attached to each other, an insertion groove portion in which an inner space is relatively expanded compared to an open space is formed at one of surfaces of the first unit panel and the second unit panel, which are closely attached to each other, and a fixing protrusion portion fixed to the insertion groove portion is formed at the other surface.

Here, it is preferable that the fixing protrusion is deformed by an external force and is press-fixed into the insertion groove portion in a state where the fixing protrusion is inserted into the insertion groove portion.

Preferably, the inner wall surface of the insertion groove portion has a first surface and a second surface that are in contact with the opening space, and the first surface and the second surface are each formed with a recessed coupling groove.

It is preferable that a guide projection is provided on a third surface facing the opening space and connecting the first surface and the second surface, in an inner wall surface of the insertion groove portion, the guide projection being constituted by first inclined surfaces symmetrical to each other, and a center of the guide projection projecting toward the opening space.

Further, it is preferable that the fixing boss includes a pair of insertion projections inserted into connection grooves recessed from the first and second faces, respectively.

Further, it is preferable that a second inclined surface for guiding a deformation direction of the insertion projection is provided at a front end of the insertion projection.

Further, it is preferable that a step is provided on the second inclined surface of the insertion projection.

Further, it is preferable that a groove is concavely formed at a portion where the second inclined surfaces connecting the pair of insertion projections are connected.

Further, it is preferable that the insertion groove portion and the fixing protrusion portion are respectively formed on faces of the reinforcing ribs facing each other.

In addition, it is preferable to include a reinforcing strip laterally disposed on the back surface of the finished panel, and flanges for supporting ends of the reinforcing strip are provided on both sides of the finished panel.

Further, it is preferable that the reinforcing strip includes: a support rod, both ends of which are inserted into and supported by the connection holes provided on the flange; and the bracket extends from one side of the supporting rod and is supported on the back of the finished panel.

In addition, it is preferable that a fixing block for fixing the support rod of the reinforcing bar to the flange is further included.

Preferably, an insertion hole is formed in the support rod of the reinforcing bar in a longitudinal direction, the fixing block is inserted into the insertion hole of the support rod, and the support rod is inserted into the connection hole of the flange.

Preferably, the support rod is fixed to the flange by expanding an outer diameter of the support rod when the front end portion of the fixing block is inserted into the insertion hole.

In addition, it is preferable that a concave-convex portion is provided on a side surface of a front end portion of the fixed block, and a region corresponding to the concave-convex portion in the reinforcing bar is pressed and fixed to the fixed block.

In addition, it is preferable that the reinforcing rib is provided with a slit into which a bracket of the reinforcing bar can be inserted.

Furthermore, the slit is preferably configured in such a shape that the bracket of the reinforcing bar is connected through.

According to the present invention, there is provided an aluminum mold panel assembly for construction that can firmly fix a pair of unit panels constituting a finished panel by means of pressing.

Further, the aluminum mold panel assembly for construction is provided, which can exert a strong fixing force even if a pressure for deforming the fixing protrusion is not completely provided in the process of pressing the pair of unit panels.

Drawings

Fig. 1 is a perspective view of an aluminum mold panel assembly for construction of the present invention.

Fig. 2 is an exploded perspective view of an aluminum mold panel assembly for construction of the present invention.

Fig. 3 is an exploded perspective view of the finished panel illustrated in fig. 2.

Fig. 4 is a rear view of the architectural aluminum mold panel assembly of the present invention.

Fig. 5 is a sectional view taken along line a-a' of fig. 4.

Fig. 6 is an operation diagram illustrating a coupling process of the first unit panel and the second unit panel shown in fig. 5.

Fig. 7 is a sectional view taken along line B-B' of fig. 4.

Fig. 8 is a cross-sectional view taken along line C-C' of fig. 4.

Description of the reference numerals

10: finished panel 11: long-edge flange

11 a: connection hole 20: short-edge flange

30: reinforcing bar 31: support rod

31 a: insertion hole 32: support frame

40: fixing block 110: first unit panel

111: first panel 112: first reinforcing rib

112 a: gap 113: insertion groove part

113 a: connection groove 113 b: guide projection

113 c: first inclined surface 120: second unit panel

121: second panel 122: second reinforcing rib

122 a: gap 122 b: pressurizing groove

123 fixing boss 123 a: insertion projection

123 b: second inclined surface 123 c: step

123 d: groove P1: pressurizing mechanism

P2: supporting block

Detailed Description

Before the present invention is explained, in the embodiments, the same reference numerals are used for members having the same structure, and the first embodiment is representatively explained, and in other embodiments, the structure different from the first embodiment is explained.

Hereinafter, an aluminum mold panel assembly for construction according to a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the accompanying drawings, fig. 1 is a perspective view of an aluminum mold panel assembly for construction of the present invention, fig. 2 is an exploded perspective view of the aluminum mold panel assembly for construction of the present invention, and fig. 3 is an exploded perspective view of a finished panel illustrated in fig. 2.

The aluminum mold panel assembly for construction of the present invention as shown in the above-mentioned drawings comprises a finished panel 10, a flange formed at the edge of the back surface of the finished panel 10, and a reinforcing bar 30 laterally disposed on the back surface of the finished panel 10.

The finished panel 10 includes a first unit panel 110 and a second unit panel 120, which are fixed in a state in which one side ends are closely attached to each other. Such first and

second unit panels

110 and 120 may be constructed of an aluminum material of light metal and prepared by an extrusion molding process using an extruder. The extrusion area becomes small when the finished panel 10 is thus constructed by being divided into the first unit panel 110 and the second unit panel 120, so that the finished panel 10 can also be prepared by an extruder having a relatively small area compared to the finished panel 10.

The first unit panel 110 includes: a rectangular first panel 111; a first reinforcing rib 112 protruding from the back surface of one end portion of the first panel 111 along the long side thereof and extending in the longitudinal direction along the long side thereof; and an insertion groove 113 formed by being recessed from the entire surface of the first reinforcing rib 112 in close contact with the second unit panel 120 and extending in the longitudinal direction parallel to the long side.

The second unit panel 120 includes: a rectangular second panel 121; a second reinforcing rib 122 protruding from the back surface of the other side end portion aligned with the long side of the second panel 121 and extending in the longitudinal direction aligned with the long side; and a fixing protrusion 123 protruding from the entire surface of the second reinforcing rib 122 in close contact with the first unit panel 110 and extending in the longitudinal direction parallel to the long side.

Specifically, the insertion groove portion 113 has a shape in which an internal space is relatively expanded than an open space, coupling grooves 113a are formed on a first face and a second face, which meet the open space, respectively, in an inner wall surface of the insertion groove portion 113, and a guide protrusion 113b configured by first inclined faces 113c whose both sides are symmetrical to each other is provided on a third face, which faces the open space and serves to couple the first face and the second face, in such a manner that the center thereof protrudes toward the open space.

Further, the fixing protrusion 123 is deformed by an external force and is press-fixed into the insertion groove 113 in a state of being inserted into the insertion groove 113, the fixing protrusion 123 includes a pair of insertion protrusions 123a inserted into the coupling grooves 113a of the insertion groove 113, a second inclined surface 123b corresponding to the first inclined surface 113c of the guide protrusion 113b for guiding a deformation direction of the insertion protrusion 123a is formed on a front end of the insertion protrusion 123a, a groove 123d is concavely formed at a portion of the fixing protrusion 123 connected to the second inclined surfaces 123b of the pair of insertion protrusions 123a, and a step 123c is formed on the second inclined surface 123b of the insertion protrusion 123a by forming such a groove 123 d. In addition, in the present embodiment, it is described that the step 123c is formed in the process of forming the groove 123d recessed from the second inclined surface 123b, but may be provided in a form protruding from the second inclined surface 123b regardless of the groove 123 d.

That is, in a state where the fixing protrusion 123 is simply inserted into the insertion groove 113 for coupling the first unit panel 110 and the second unit panel 120, the second inclined surface 123b of the insertion protrusion 123a is disposed in contact with or close to the guide protrusion 113b, and the convex vertex contacting the first inclined surface 113c on both sides of the guide protrusion 113b is disposed at a position corresponding to the concave bottom point of the concave groove 123 d. At this time, the interval between the convex peak of the guide protrusion 113b and the concave bottom point of the groove 123d is set relatively larger than the interval between the second inclined surface 123b of the insertion protrusion 123a and the first inclined surface 113c of the guide protrusion 113 b. Further, the step 123c formed on the second inclined surface 123b of the insertion protrusion 123a is located above the first inclined surface 113c of the guide protrusion 113b (see (a) of fig. 6).

In addition, the rear face of the first reinforcing rib 112 is a supporting face which can be supported by the supporting block P2, and the rear face of the second reinforcing rib 122 is a pressing face which can be pressed by the pressing mechanism P1. In the process of pressing by the pressing mechanism P1 for deformation of the fixing protrusion 123, it is preferable that a pressing groove 122b is concavely formed on the pressing surface, and the volume of the pressing groove 122b is set to correspond to the amount of deformation of the fixing protrusion 123 in the insertion groove portion 113. Here, when the pressing mechanism P1 is configured in the form of a pressing pin that strikes the pressing surface, the pressing groove 122b may be formed in plurality on the striking surface of the second reinforcing rib 122 in the lengthwise direction of the second reinforcing rib 122, and when the pressing mechanism P1 is configured in the form of a pressing roller, the pressing groove 122b may be formed on the pressing surface of the second reinforcing rib 122 in the form of a rail groove that extends in the lengthwise direction of the second reinforcing rib 122 (see (c) of fig. 6).

When the first unit panel 110 and the second unit panel 120 constituting the finished panel 10 are fixed by the press method as described above, the thickness of the panel can be made thinner than that of the conventional welding method, and therefore, further weight reduction can be achieved.

The flanges may be formed of long-side flanges 11 disposed at both side ends of the finished panel 10 and short-side flanges 20 disposed at upper and lower ends of the finished panel 10, the long-side flanges 11 may be integrally formed with the finished panel 10, and the short-side flanges 20 may be fixed to the finished panel 10 by additional processes such as rivets or welding.

The reinforcing strip 30 includes: a support bar 31 having an insertion hole 31a formed in an inner longitudinal direction thereof, and both ends inserted into and supported by connection holes 11a formed in the long-side flange 11; and a bracket 32 extending from one side of the support bar 31 and supported on the rear surface of the finished panel 10.

Such reinforcing bars 30 are disposed side by side with the short-side flanges 20 and are provided in plural, and the plural reinforcing bars 30 are disposed at intervals in the direction side by side with the long-side flanges 11, and the intervals of the intervals can be adjusted according to the magnitude of the surface pressure acting on the finished panel 10, so as to effectively support the surface pressure acting on the finished panel 10 at the time of pouring and curing of concrete.

Slits

112a and 122a for attaching the reinforcing bar 30 are provided in the first reinforcing rib 112 and the second reinforcing rib 122, respectively, and when the bracket 32 of the reinforcing bar 30 is inserted into the

slits

112a and 122a, one surface of the bracket 32 can be supported in a state of surface contact with the back surface of the finished panel 10.

In addition, the

slits

112a and 122a are preferably configured to be able to connect the brackets 32 of the reinforcing bar 30 penetrating the first reinforcing rib 112 and the second reinforcing rib 122 so that the reinforcing bar 30 can be fixed in the thickness direction of the finished panel 10 (see fig. 8).

Further, a fixing block 40 for fixing the support rod 31 to the long side flange 11 may be coupled to the insertion hole 31a of the support rod 31 inserted into the coupling hole 11a of the long side flange 11.

At this time, the front end portion of the fixing block 40 may be configured to expand the outer diameter of the support rod 31 when being pressed into the insertion hole 31a, thereby enabling the support rod 31 to be fixed to the long side flange 11.

Further, a plurality of concave and convex portions 41 are provided on the side surface of the front end portion of the fixing block 40, and as the region of the reinforcing bar 30 corresponding to the concave and convex portions 41 is pressed, the fixing force of the reinforcing bar 30 to the fixing block 40 can be improved while preventing the fixing block 40 from being arbitrarily detached from the insertion hole 31a of the reinforcing bar 30 (see fig. 7).

Next, the operation of the first embodiment of the above-described aluminum mold panel assembly for construction will be explained.

In the drawings, fig. 4 is a rear view of an aluminum mold panel assembly for construction of the present invention, fig. 5 is a sectional view taken along line a-a ' of fig. 4, fig. 6 is an operation view illustrating a coupling process of a first unit panel and a second unit panel shown in fig. 5, fig. 7 is a sectional view taken along line B-B ' of fig. 4, and fig. 8 is a sectional view taken along line C-C ' of fig. 4.

First, as shown in fig. 4, the first unit panel 110 and the second unit panel 120 are coupled to each other to form a finished panel 10, short-side flanges 20 are assembled to the upper end of the finished panel 10, and reinforcing bars 130 are assembled between long-side flanges 11 disposed on both sides of the finished panel 10.

In this way, the short-side flange 20 and the long-side flange 11 are arranged at the edge of the finished panel 10, the first reinforcing rib 112 and the second reinforcing rib 122 are arranged in the direction parallel to the long side on the back surface of the finished panel 10, and the plurality of reinforcing beads 30 are arranged in the direction parallel to the short side, so that the load applied to the finished panel 10 can be effectively supported while the weight of the mold is reduced.

As shown in fig. 5, in the first unit panel 110 and the second unit panel 120 constituting the finished panel 10, in a state where the fixing protrusion 123 provided on the second reinforcing rib 122 of the second finished panel 10 is inserted into the insertion groove portion 113 formed on the first reinforcing rib 112 of the first finished panel 10, the fixing protrusion 123 is permanently deformed by external pressure and pressed into the insertion groove portion 113, thereby being firmly fixed.

Specifically, as shown in fig. 6 (a), when the first reinforcing rib 112 of the first unit panel 110 and the second reinforcing rib 122 of the second unit panel 120 are closely attached to each other, the fixing protrusion 123 of the second reinforcing rib 122 is inserted into the insertion groove 113 of the first reinforcing rib 112.

That is, in a state where the fixing protrusion 123 is simply inserted into the insertion groove portion 113, the second inclined surface 123b of the insertion protrusion 123a is disposed in contact with or close to the guide protrusion 113b, and the convex apex contacting the first inclined surface 113c on both sides of the guide protrusion 113b is disposed at a position corresponding to the concave bottom point of the concave groove 123 d.

At this time, the interval between the convex peak of the guide protrusion 113b and the concave bottom point of the groove 123d is set relatively larger than the interval between the second inclined surface 123b of the insertion protrusion 123a and the first inclined surface 113c of the guide protrusion 113 b. Further, the step 123c formed on the second inclined surface 123b of the insertion protrusion 123a is located on the first inclined surface 113c of the guide protrusion 113 b.

Then, as shown in fig. 6 (b), while the area corresponding to the fixing protrusion 123 in the rear face of the second reinforcing rib 122 is pressurized by the pressurizing mechanism P1 in a state where the rear face of the first reinforcing rib 112 is supported by the support block P2, the fixing protrusion 123 inserted inside the insertion groove portion 113 is deformed and moved toward the guide protrusion 113b of the insertion groove portion 113 while the rear face of the second reinforcing rib 122 is concavely formed into the pressurizing groove 122 b.

That is, in the process of the entire fixing protrusion 123 moving toward the guide protrusion 113b, after the step 123c provided at the second inclined surface 123b comes into contact with the first inclined surface 113c, the concave bottom point of the groove 123d comes into contact with the convex top point of the guide protrusion 113 b. At this time, the step 123c, which is first in contact with the first inclined surface 113c, functions as the holder 32, so that the front end portion of the insertion projection 123a is spaced apart from the first inclined surface 113c and moves toward the coupling groove 113 a.

In this manner, during the pressing of the fixing protrusion 123, the front end portion of the insertion protrusion 123a may contact the coupling groove 113a to provide a fixing force generated by the pressing, and thus a strong fixing force can be exerted even if complete pressing is not achieved.

Then, as shown in fig. 6 (c), the insertion projection 123a of the fixing projection 123 is completely fitted into the coupling groove 113a of the insertion groove 113 while the fixing projection 123 is further deformed by the pressing force of the pressing mechanism P1. At this time, the inner space of the insertion groove portion 113 is expanded more than the opening space, and thus the fixing protrusion 123 can be prevented from being detached from the insertion groove portion 113, thereby firmly fixing the first unit panel 110 and the second unit panel 120.

In addition, in the present embodiment, the deformation process of the fixing protrusion 123 by the pressurization mechanism P1 is described as being divided into (b) and (c) of fig. 6, but this is not to be understood as being accomplished by a separate additional process, but is to be understood as finally being deformed into the shape shown in (c) of fig. 6 after the fixing protrusion 123 is subjected to the process shown in (b) of fig. 6 by one pressurization process using the pressurization mechanism P1.

As shown in fig. 7 and 8, the reinforcing bar 30 is disposed on the back surface of the finished panel 10 in a direction parallel to the short side of the finished panel 10, and the support rod 31 of the reinforcing bar 30 is fixed to the long-side flange 11 by the fixing block 40 press-fitted into the insertion hole 31a of the support rod 31 in a state where both ends of the support rod 31 are inserted into the connection holes 11a of the long-side flange 11. That is, the outer diameter of the support rod 31 inserted into the coupling hole 11a is expanded during the press-fitting of the fixing block 40, so that the support rod 31 can be firmly fixed in the coupling hole 11 a.

Further, when the bracket 32 of the reinforcing bar 30 is inserted into the

slits

112a and 122a formed in the first reinforcing rib 112 and the second reinforcing rib 122, respectively, the entire surface of the bracket 32 is closely supported on the rear surface of the finished panel 10, and thus the load applied to the finished panel 10 can be effectively supported.

The scope of the claims of the present invention is not limited to the above-described embodiments, but may be embodied in various forms within the scope of the appended claims. Various modifications to the present invention can be made by those skilled in the art without departing from the spirit of the present invention claimed in the claims.

Claims

1. An aluminum die panel component for buildings is characterized in that,

comprising a first unit panel and a second unit panel for constituting a finished panel,

reinforcing ribs are formed at one side end portion of the first unit panel and one side end portion of the second unit panel, respectively, the one side end portions being fixed in a state of being in close contact with each other,

an insertion groove portion in which an inner space is expanded relative to an opening space is formed in one of surfaces of the first unit panel and the second unit panel which are in close contact with each other, and a fixing protrusion portion which is fixed to the insertion groove portion is formed in the other surface.

2. An architectural aluminum mold panel assembly according to claim 1,

in a state where the fixing protrusion is inserted into the insertion groove portion, a shape of the fixing protrusion is deformed by an external force and is press-fixed into the insertion groove portion.

3. An architectural aluminum mold panel assembly according to claim 2,

in the inner wall surface of the insertion groove portion, a connection groove is formed in a recessed manner in each of a first surface and a second surface that are in contact with the opening space.

4. An architectural aluminum mold panel assembly according to claim 3,

a guide projection is provided on a third surface facing the opening space and connecting the first surface and the second surface, in an inner wall surface of the insertion groove portion,

the guide protrusion is formed of first inclined surfaces symmetrical to each other, and a center of the guide protrusion protrudes toward the opening space.

5. An architectural aluminum mold panel assembly according to claim 3,

the fixing boss includes a pair of insertion projections inserted into connection grooves recessed from the first and second faces, respectively.

6. An architectural aluminum mold panel assembly according to claim 5,

a second inclined surface for guiding a deformation direction of the insertion projection is provided at a front end of the insertion projection.

7. An architectural aluminum mold panel assembly according to claim 6,

a step is provided on the second inclined surface of the insertion projection.

8. An architectural aluminum mold panel assembly according to claim 6,

a groove is concavely formed on the connecting part of the second inclined planes of the pair of inserting bulges.

9. An architectural aluminum mold panel assembly according to claim 1,

the insertion groove portions and the fixing protrusion portions are respectively formed on the faces of the reinforcing ribs facing each other.

10. An architectural aluminum mold panel assembly according to claim 1,

comprising a reinforcing strip arranged transversely on the rear face of the finished panel,

flanges for supporting the ends of the reinforcing strips are arranged on the two sides of the finished panel.

11. An architectural aluminum mold panel assembly according to claim 10,

the reinforcing strip includes: a support rod, both ends of which are inserted into and supported by the connection holes provided on the flange; and the bracket extends from one side of the supporting rod and is supported on the back of the finished panel.

12. An aluminum mold panel assembly for construction as set forth in claim 11,

the fixing block is used for fixing the supporting rod of the reinforcing bar on the flange.

13. An architectural aluminum mold panel assembly according to claim 12,

an insertion hole is formed inside the support rod of the reinforcing bar in a length direction,

the fixing block is inserted into the insertion hole of the support rod, and the support rod is inserted into the connection hole of the flange.

14. An architectural aluminum mold panel assembly according to claim 13,

and expanding the outer diameter of the support rod when the front end part of the fixing block is inserted into the insertion hole, so that the support rod is fixed on the flange.

15. An architectural aluminum mold panel assembly according to claim 14,

a concave-convex portion is provided on a side surface of a front end portion of the fixing block, and a region corresponding to the concave-convex portion in the reinforcing bar is pressed and fixed to the fixing block.

16. An aluminum mold panel assembly for construction as set forth in claim 11,

gaps into which the brackets of the reinforcing bars can be inserted are formed in the reinforcing ribs.

17. An architectural aluminum mold panel assembly according to claim 16,

the slit is configured in a shape that allows the bracket of the reinforcing bar to be connected therethrough.