KR20240013523A - Full precast concrete structure - Google Patents

Abstract

The present invention consists of an All PC of a plurality of PC columns, PC girders, PC walls, and PC slabs. By converting not only columns and girders but also slabs and walls into All PCs, on-site reinforcement or concrete pouring work is omitted, and air is saved. It is about a fully assembled PC structure that can be shortened.
The present invention is installed to be spaced apart from each other and includes a plurality of PC pillars formed with an L-shaped or T-shaped cross-section; A PC girder installed between the PC pillars and having an end joined to the side of the PC pillar; A PC wall installed between PC pillars on both sides and upper and lower PC girders installed vertically between the PC pillars, and the ends of which are joined to the sides of the PC pillars; And a PC slab installed between the PC girders and whose ends are joined to the sides of the PC girders; It is composed of a first pocket portion formed at both ends of the PC wall, and inside the first pocket portion, a box-shaped joint block with both sides open is accommodated with an elongated bolt fastening hole in the front center, and the PC pillar. A first fixing socket is embedded in the side of the joint block at a position corresponding to the joint block, and the PC wall and the PC pillar are joined by a joint bolt that penetrates the bolt fastening hole of the joint block and is screwed to the first fixing socket. It is characterized by

Description

Full precast concrete structure}

The present invention consists of an All PC of a plurality of PC columns, PC girders, PC walls, and PC slabs. By converting not only columns and girders but also slabs and walls into All PCs, on-site reinforcement or concrete pouring work is omitted, and air is saved. It is about a fully assembled PC structure that can be shortened.

The cast-in-place reinforced concrete method, in which various structures are completed by arranging rebar and installing formwork on site and then pouring concrete, is greatly influenced by the site environment and weather conditions and is labor-intensive, so labor costs are high. In addition, concrete curing time is required, which limits shortening the construction period and makes quality control difficult.

In particular, apartment complexes are equipped with rooftop structures on the top floor of the building for elevator halls, machine rooms, staircases, etc., and these rooftop structures have a different plan shape from the lower floors. Therefore, it is impossible to use the large formwork used in the construction of the lower floor, so it is mainly constructed using the conventional RC method. However, since rooftop structures are constructed after most of the framing work has been completed, there are difficulties in supplying manpower for the process or supplying concrete for on-site pouring.

Accordingly, the application of the precast concrete method, which produces members at the factory and assembles them on site, is increasing, and after the full-scale implementation of the 52-hour workweek or the ready-mixed concrete 85 system, difficulties in operating field personnel and supplying concrete have increased, so PC Interest in is increasing.

However, the PC method involves assembling pre-fabricated members on site, making it difficult to process joints between members.

Previously registered utility model No. 20-0414349 discloses a technology for forming a ramen structure by placing a PC girder on the top of a PC column and pouring and integrating in-situ concrete between the upper and lower PC columns and on the top of the PC girder. In the above registration technology, in the case of a slab, a deck plate or half PC slab is placed on the top of the PC girder and topping concrete is poured on the top, and in the case of a wall, a separate finishing material is attached to finish it.

However, this conventional technology is a half-PC method and involves separate reinforcement or concrete pouring work on site after assembling PC members, so there is a limit to shortening the construction period. In addition, there are still problems that are inevitably influenced by on-site manpower and concrete supply and demand conditions.

In order to solve the above problems, the present invention aims to provide a fully assembled PC structure that can reduce the construction period by omitting on-site rebar placement or concrete pouring work by converting not only columns and girders but also slabs and walls into all PCs. .

The present invention according to a preferred embodiment includes a plurality of PC pillars that are installed spaced apart from each other and are formed with an L-shaped or T-shaped cross-section; A PC girder installed between the PC pillars and having an end joined to the side of the PC pillar; A PC wall installed between PC pillars on both sides and upper and lower PC girders installed vertically between the PC pillars, and the ends of which are joined to the sides of the PC pillars; And a PC slab installed between the PC girders and whose ends are joined to the sides of the PC girders; It is composed of a first pocket portion formed at both ends of the PC wall, and inside the first pocket portion, a box-shaped joint block with both sides open is accommodated with an elongated bolt fastening hole in the front center, and the PC pillar. A first fixing socket is embedded in the side of the joint block at a position corresponding to the joint block, and the PC wall and the PC pillar are joined by a joint bolt that penetrates the bolt fastening hole of the joint block and is screwed to the first fixing socket. Provides a fully assembled PC structure featuring:

According to another preferred embodiment of the present invention, second pockets are formed on both sides of the ends of the PC girder, couplers are embedded in the upper and lower sides of the inner ends of the second pockets, and a position corresponding to the coupler is located on the side of the PC pillar. A second fixing socket is embedded in the bar body, and the rear end of the bar body with a head formed at the front end of the bar body is screwed to the coupler, the head part is received inside the second fixing socket, and the outside of the bar body A fully assembled PC structure, characterized in that a fixing cap screwed to the inner peripheral surface of the second fixing socket pressurizes and fixes the head of the headed bar to the inside of the second fixing socket, thereby connecting the PC girder and the PC pillar. provides.

In the present invention according to another preferred embodiment, a mounting groove is formed in the lower side of the PC slab, a third fixing socket is embedded in the side of the PC girder at a position corresponding to the mounting groove, and the front end is fixed to the third fixation. A fully assembled type that is screwed into the inside of the socket, and the rear end is mounted on the upper part of the holder so that a holder protruding from the side of the PC girder is inserted into the mount groove, so that the PC slab and the PC girder are joined. Provides PC structure.

According to the present invention, it is composed of an All PC of a plurality of PC columns, PC girders, PC walls, and PC slabs, and not only columns and girders, but also slabs and walls are all PC, thereby omitting on-site reinforcement or concrete pouring work and saving time. A fully assembled PC structure that can shorten can be provided.

In particular, since the PC wall is inserted inside the frame formed by the PC column and PC girder, the PC wall can serve as a filling wall to improve the lateral force resistance of the structure.

In addition, since the end of the PC girder is directly connected to the side of the PC column, there is no need for an on-site concrete pouring process for joining the upper and lower PC columns or between the PC column and the PC girder.

In addition, since the PC slab is installed inside the space surrounded by the PC girder, the end of the PC slab is directly connected to the PC girder, eliminating the need for an on-site concrete pouring process to integrate the PC girder and PC slab.

1 is a perspective view showing a fully assembled PC structure of the present invention.
Figure 2 is a perspective view showing the coupling relationship between a PC wall and a PC pillar.
Figure 3 is an elevation cross-sectional view showing the connection relationship between the PC wall and the PC column.
Figure 4 is a perspective view showing a PC girder in which a headed bar and a fixed cap are combined.
Figure 5 is a perspective view showing the coupling relationship between the headed bar and the main bar.
Figure 6 is a perspective view showing the details of the connection between the headed bar and the second fixing socket.
Figure 7 is a cross-sectional view showing the connection relationship between a PC column and a PC girder.
Figure 8 is a perspective view showing the coupling relationship between the third fixing socket and the holder.
Figure 9 is a bottom perspective view showing the coupling relationship between the support and the PC slab.
Figure 10 is a bottom perspective view showing the combined state of the mounting fixture and the PC slab.
Figure 11 is a cross-sectional view showing a combined state of a PC slab and a PC girder.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

Figure 1 is a perspective view showing the fully assembled PC structure of the present invention, Figure 2 is a perspective view showing the coupling relationship between the PC wall and the PC pillar, and Figure 3 is an elevation cross-sectional view showing the coupling relationship between the PC wall and the PC pillar. .

As shown in Figures 1 to 3, the fully assembled PC structure of the present invention includes a plurality of PC pillars 1 that are installed spaced apart from each other and are formed in an L-shaped or T-shaped cross-section; A PC girder (2) installed between the PC pillars (1) and whose ends are joined to the side of the PC pillar (1); A PC wall (3) installed between the PC pillars (1) on both sides and the upper and lower PC girders (2) installed vertically between the PC pillars (1), the ends of which are joined to the side of the PC pillar (1); And a PC slab (4) installed between the PC girders (2) and whose ends are joined to the side of the PC girders (2); It is composed of a first pocket part 31 formed at both ends of the PC wall 3, and the inside of the first pocket part 31 is box-shaped with both sides open, and is fastened with a bolt of a long hole extending vertically in the front center. A joining block 32 formed with a ball 321 is accommodated, and a first fixing socket 11 is embedded in the side of the PC pillar 1 at a position corresponding to the joining block 32, and the joining block ( It is characterized in that the PC wall (3) and the PC pillar (1) are joined by a joining bolt (5) that passes through the bolt fastening hole (321) of 32) and is screwed to the first fixing socket (11).

The present invention is intended to provide a fully assembled PC structure that can omit on-site reinforcement or concrete pouring work and shorten the construction period by converting not only columns and girders but also slabs and walls into all PCs.

The fully assembled PC structure of the present invention is composed of a plurality of PC columns (1), PC girders (2), PC walls (3), and PC slabs (4), making it All PC.

A plurality of the PC pillars 1 are installed to be spaced apart from each other.

The PC pillar (1) can be installed at each corner of the structure.

The PC pillar 1 is formed with an L-shaped or T-shaped cross section.

Accordingly, by forming the same surface as the PC girder (2) or PC wall (3), the cross-sectional area of the PC pillar (1) can be secured as much as possible while preventing the PC pillar (1) from protruding inside and outside, and the protrusion is not protruded inside or outside. Easy to finish.

The PC girders (2) are installed between the PC columns (1) at each floor location.

Unlike the conventional PC method in which the PC girder is mounted on the top of the PC column, the end of the PC girder (2) is coupled to the side of the PC column (1) and is directly joined.

Accordingly, even when the PC pillar (1) is mainly formed as a single multi-layered section, the PC pillar (1) can be formed continuously without segmentation. And since the PC column (1) is continuous up and down, there is no need for a concrete on-site pouring process to join the upper and lower PC columns (1) or to connect the PC column (1) and the PC girder (2).

The PC column (1) and PC girder (2) form a frame to form a ramen structure.

The PC wall (3) is installed between the PC pillars (1) on both sides and the upper and lower PC girders (2) installed vertically between the PC pillars (1), and the ends are joined to the side of the PC pillar (1). .

That is, the PC wall 3 is inserted into the frame formed by the PC pillar 1 and the PC girder 2, and the end of the PC wall 3 is directly connected to the side of the PC pillar 1.

The top and bottom of the PC wall (3) can be directly connected to the lower surface of the upper PC girder (2) and the upper surface of the lower PC girder (2), respectively.

The PC wall (3) serves as a filling wall inside the frame composed of the PC column (1) and the PC girder (2), thereby improving the lateral force resistance of the structure.

The PC slab (4) is installed between the PC girders (2) and its ends are joined to the side of the PC girders (2).

That is, the PC slab (4) is installed inside the space surrounded by the PC girder (2), and its end is joined to the side of the PC girder (2).

Since the end of the PC slab (4) is directly connected to the PC girder (2), there is no need for an on-site concrete pouring process to integrate the PC girder (2) and PC slab (4).

The upper surface of the PC slab (4) can be installed to be at the same height as the upper surface of the PC girder (2).

The PC wall (3) and the PC pillar (1) are joined by a joining bolt (5).

For this purpose, joint blocks 32 are provided on both side ends of the PC wall 3, and a first fixing socket 11 is provided on the side of the PC pillar 1 at a position corresponding to the joint block 32. It is landfilled.

The connecting bolt (5) passes through the bolt fastening hole (321) formed at the front center of the connecting block (32) and is screwed to the first fixing socket (11) to connect the PC wall (3) and the PC pillar (1). do.

Specifically, the first fixing socket 11 is embedded inside the side of the PC pillar 1 on the side where the PC wall 3 is joined.

The first fixing socket 11 may be formed by tapping the end of a steel bar penetrating the inside of the PC pillar 1.

The joint block 32 can be configured as a ㅁ-shaped box with both sides open, and is accommodated in the first pocket portion 31 formed on the side end of the PC wall 3 at a position corresponding to the first fixing socket 11. do.

A bolt fastening hole 321 for fastening the joining bolt 5 is formed in the joining block 32.

A fixing bar 33 embedded in the PC wall 3 may be coupled to the back of the joining block 32.

The joining bolt (5) penetrates the bolt fastening hole (321) inside the joining block (32) and is screwed to the first fixing socket (11) to secure the joining block (32) to the first fixing socket (11). , Connect the PC wall (3) to the PC pillar (1).

Meanwhile, due to construction or manufacturing errors, the positions between the bolt fastening hole 321 on the PC wall 3 side and the first fixing socket 11 of the PC pillar 1 may not match each other. Therefore, the bolt fastening hole 321 is formed as a long hole with a long length up and down to absorb such errors.

After fastening the joint bolt (5), mortar (M) can be filled inside the joint block (32) of the PC wall (3) and in the space between the PC pillar (1) and the PC wall (3) (Figure 3 ).

A simple plate (35) can be inserted between the joint block (32) and the face of the PC pillar (1) according to the gap in order to fix the position of the PC wall (3) and firmly tighten the joint bolt (5).

Since the first fixing socket 11 and the joining block 32 do not protrude to the outside of the PC pillar 1 and the PC wall 3, respectively, there is no interference factor when installing the PC member.

Figure 4 is a perspective view showing a PC girder in which a headed bar and a fixed cap are combined, Figure 5 is a perspective view showing the connection relationship between the headed bar and the main bar, and Figure 6 shows the details of the connection between the headed bar and the second fixed socket. This is a perspective view. And Figure 7 is a cross-sectional view showing the connection relationship between the PC column and the PC girder.

As shown in Figures 4 to 7, second pocket parts 21 are formed on both sides of the end of the PC girder 2, and couplers 22 are provided vertically at the inner end of the second pocket part 21. is embedded, and a second fixing socket 12 is embedded in the side of the PC pillar 1 at a position corresponding to the coupler 22, and a head portion 62 is formed at the front end of the bar body 61. The rear end of the bar body 61 of the did bar 6 is screwed to the coupler 22, and the head portion 62 is accommodated inside the second fixing socket 12, and the bar body 61 The fixing cap 7, which is provided on the outside and is screwed to the inner peripheral surface of the second fixing socket 12, pressurizes and fixes the head portion 62 of the headed bar 6 to the inside of the second fixing socket 12. The PC girder (2) and the PC column (1) can be joined.

The PC girder (2) and PC pillar (1) can be joined by a headed bar (6) and a fixing cap (7).

For this purpose, a coupler 22 to which the rear end of the bar body 61 of the headed bar 6 is screwed may be embedded in the end of the PC girder 2. In addition, a second fixing socket 12 into which the head portion 62 of the headed bar 6 is inserted can be installed on the side of the PC pillar 1 at a position corresponding to the coupler 22.

The second fixing socket 12 has a front-open receiving space 121 formed therein, and a female thread may be formed on the inner peripheral surface of the receiving space 121.

A headed bar (6) may be coupled to the end of the PC girder (2).

The headed bar 6 may be connected to the main bar 20 and the coupler 22 placed inside the PC girder 2.

The fixing cap 7 may have a through hole 71 formed in the center so that the bar body 61 of the headed bar 6 penetrates.

The through hole 71 has a larger diameter than the bar body 61 and a smaller diameter than the head portion 62, so that the head portion 62 of the headed bar 6 is caught on the front end of the fixing cap 7. You can.

A thread is formed on the outer peripheral surface of the fixing cap 7 and can be screwed to a female thread formed on the inner peripheral surface of the receiving space 121 of the second fixing socket 12.

That is, as shown in (a) of FIG. 6, with the fixing cap 7 provided on the outside of the bar body 61 of the headed bar 6, the head portion 62 of the headed bar 6 is After inserting it into the receiving space 121 of the second fixing socket 12 ((b) in FIG. 6), the fixing cap 7 is rotated to insert it into the receiving space 121 of the second fixing socket 12. While moving, the head portion 62 of the headed bar 6 can be pressed and brought into close contact with the bottom surface of the receiving space 121 (FIGS. 6(c) and 5).

The headed bar (6) is continuous with the main bar (20) of the PC girder (2) and transmits the tensile or compressive force for the bending moment of the joint to the inside of the PC column (1).

That is, when a compressive force occurs at the joint, the head portion 62 of the headed bar 6 is in close contact with the bottom of the receiving space 121 of the second fixing socket 12 and the second fixing socket 12 is subjected to bearing force. The load is directly transmitted to the fixing bar (13) at the rear of the fixing socket (12).

Conversely, when tension occurs at the joint, the head portion 62 of the headed bar 6 is caught on the fixing cap 7 and transfers the load to the fixing bar 13 by tension of the second fixing socket 12. .

A second pocket portion 21 may be formed on the upper and lower ends of the PC girder 2 to secure a work space for fastening the fixing cap 7 and the second fixing socket 12.

The second pocket portion 21 is formed on the left and right sides of the PC girder 2, respectively, and the coupler 22 is provided at the upper and lower portions of each second pocket portion 21 and is attached to each coupler 22. Didbar (6) can be combined.

After completing the joining of the PC girder (2) and the PC column (1), mortar (M) can be filled in the second pocket portion (21) and the space between the PC column (1) and the PC girder (2). .

As described above, in the present invention, the headed bar (6) provided with the fixing cap (7) on the outer peripheral surface is coupled to the end of the PC girder (2) and the fixing cap (7) is rotated to secure the PC pillar (1). Since the connection is possible simply by screwing into the second fixing socket (12) embedded in the side, the connection work between the PC column (1) and the PC girder (2) can be easily performed without an additional power source.

In addition, since the fixing cap (7) is screwed into the receiving space (121) of the second fixing socket (12) to fix the headed bar (6), the second fixing socket (12) is attached to the outside of the PC pillar (1). It does not protrude.

That is, the second fixing socket 12 embedded in the PC pillar 1 forms the same surface as the PC pillar 1, and therefore does not protrude outside the PC pillar 1.

The multi-layer, single-column PC column (1) can be manufactured as one piece without column segments, so the manufacturing efficiency of the PC member is excellent and member management is easy.

Figure 8 is a perspective view showing the coupling relationship between the third fixing socket and the holder, Figure 9 is a bottom perspective view showing the coupling relationship between the holder and the PC slab, and Figure 10 is a bottom perspective view showing the coupling state between the holder and the PC slab. am. And Figure 11 is a cross-sectional view showing the combined state of the PC slab and PC girder.

As shown in FIGS. 8 to 11, a mounting groove 41 is formed at the lower side of the PC slab 4, and a mounting groove 41 is formed on the side of the PC girder 2 at a position corresponding to the mounting groove 41. The third fixing socket 23 is embedded, the front end is screwed to the inside of the third fixing socket 23, and the rear end has a mounting hole 8 protruding from the side of the PC girder 2, which is the mounting groove ( The PC slab (4) is mounted on the top of the holder (8) so that it can be inserted into 41), so that the PC slab (4) and the PC girder (2) can be joined.

The PC slab (4) can be mounted and coupled to the upper part of the mounting bracket (8) protruding from the side of the PC girder (2).

For this purpose, a mounting groove 41 is formed in the lower part of the side end of the PC slab 4, and a third fixing socket 23 is embedded in the side of the PC girder 2 at a position corresponding to the mounting groove 41. The holder (8) can be configured to be coupled to the third fixing socket (23).

At this time, when installing the PC slab (4), interference may occur with the mounting bracket (8) protruding from the PC girder (2) of the upper layer. Therefore, it is desirable to configure the holder 8 to be detachable from the third fixing socket 23 so that it can be installed later.

Accordingly, in an embodiment for combining the third fixing socket 23 and the holder 8, a female thread is formed on the inner peripheral surface of the third fixing socket 23 and a screw thread is formed on the outer peripheral surface of the holder 8. , the holder (8) can be screwed to the inside of the third fixing socket (23).

A fixing bar 24 may be coupled to the rear end of the third fixing socket 23 to fix the third fixing socket 23 inside the PC girder 2.

The PC slab (4) can be mounted and coupled to the upper part of the mounting device (8). At this time, a mounting groove 41 into which the mounting device 8 is inserted and accommodated may be formed on the lower surface of the PC slab (4) so that the mounting device (8) does not protrude to the lower part of the PC slab (4).

The load of the PC slab (4) is transmitted to the PC girder (2) by the shear force of the holder (8).

A flange 81 is protruding from the outer peripheral surface of the rear end of the holder 8, and a locking groove 411 through which the upper part of the flange 81 of the holder 8 is inserted can be formed in the mounting groove 41. there is.

In this case, the upper part of the flange 81 of the holder 8 is inserted into the locking groove 411 provided in the mounting groove 41 of the PC slab 4, so that the PC slab 4 is attached to the upper part of the holder 8. It is possible to prevent the PC slab (4) from moving when mounted on it.

As shown in FIG. 11, in order to more firmly and stably join the PC slab (4) to the PC girder (2), a receiving hole (42) communicating with the mounting groove (41) is provided inside the PC slab (4). ) can be formed and a dowel bar 43 is provided inside the receiving hole 42 so that the dowel bar 43 is coupled to the holder (8).

The interior of the receiving hole 42 can be filled with mortar (M) to integrate the dowel bar (43) with the PC slab (4).

The dowel bar 43 can be fixed by inserting the front end into the insertion hole 82 formed at the rear end of the holder 8.

The dowel bar 43 can be screwed to the insertion hole 82. Alternatively, the dowel bar 43 can be integrated with the holder 8 by the mortar M filled with the mortar M charged inside the receiving hole 42 to the inside of the insertion hole 82. .

The worker inserts and fixes the front end of the dowel bar (43) located inside the receiving hole (42) into the insertion hole (82) of the mounting hole (8), and smoothly spreads the mortar (M) inside the receiving hole (42). A working hole 44 communicating with the inner end of the receiving hole 42 may be formed on the upper surface of the PC slab 4 to enable easy charging.

1: PC pillar 11: First fixed socket
12: Second fixed socket 121: Accommodating space
13: Anchoring bar 2: PC girder
20: Main root 21: Second pocket part
22: Coupler 23: Third fixed socket
24: Fixing bar 3: PC wall
31: first pocket part 32: joint block
321: Bolt fastener 33: Fixing bar
35: Simple plate 4: PC slab
41: Holding groove 411: Locking groove
42: receiving hole 43: dowel bar
44: Worker 5: Joint bolt
6: Headed bar 61: Bar body
62: Head part 7: Fixed cap
71: Through hole 8: Mounting hole
81: Flange 82: Insertion hole
M: mortar

Claims (3)

A plurality of PC pillars (1) installed to be spaced apart from each other and formed with an L-shaped or T-shaped cross section; A PC girder (2) installed between the PC pillars (1) and whose ends are joined to the side of the PC pillar (1); A PC wall (3) installed between the PC pillars (1) on both sides and the upper and lower PC girders (2) installed vertically between the PC pillars (1), the ends of which are joined to the side of the PC pillar (1); And a PC slab (4) installed between the PC girders (2) and whose ends are joined to the side of the PC girders (2); It consists of,
First pocket portions 31 are formed at both ends of the PC wall 3, and inside the first pocket portion 31 is a box-shaped box with open sides, and an elongated bolt fastening hole 321 at the front center. This formed joint block 32 is accommodated, and a first fixing socket 11 is embedded in the side of the PC pillar 1 at a position corresponding to the joint block 32, and the bolt of the joint block 32 A fully assembled PC structure characterized in that the PC wall (3) and the PC pillar (1) are joined by a joining bolt (5) that passes through the fastening hole (321) and is screwed to the first fixing socket (11).
In paragraph 1:
Second pocket portions 21 are formed on both sides of the ends of the PC girder 2, and couplers 22 are embedded in the inner ends of the second pocket portion 21 in the upper and lower directions, respectively, and the PC pillar 1 A second fixing socket 12 is embedded on the side at a position corresponding to the coupler 22, and the bar body 61 of the headed bar 6 is formed with a head portion 62 at the front end of the bar body 61. ) The rear end is screwed to the coupler 22, the head portion 62 is accommodated inside the second fixing socket 12, and is provided on the outside of the bar body 61. ), the fixing cap (7) screwed to the inner peripheral surface of the head bar (6) pressurizes and secures the head part (62) of the headed bar (6) to the inside of the second fixing socket (12) to secure the PC girder (2) and PC pillar (1) A fully assembled PC structure characterized by being joined.
In paragraph 1:
A mounting groove 41 is formed in the lower part of the side end of the PC slab 4, and a third fixing socket 23 is embedded in the side of the PC girder 2 at a position corresponding to the mounting groove 41, The front end is screwed into the inside of the third fixing socket 23, and the rear end is a PC slab (4) so that the mounting hole (8) protruding from the side of the PC girder (2) is inserted into the mounting groove (41). A fully assembled PC structure, characterized in that it is mounted on the top of the mounting bracket (8) and connected to the PC slab (4) and PC girder (2).

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