KR20240022842A - Modular structure for rooftop machinery room - Google Patents

Abstract

The present invention applies a modular system to the elevator machine room to shorten the construction period and improve constructability, and increases the bending rigidity by combining horizontal members with bonding bolts during stacking construction of the upper and lower modular units, thereby reducing the weight of the modular unit and efficiently handling the equipment load. It is about a modular structure for a rooftop machine room that can be supported.
The rooftop machine room modular structure of the present invention is installed on the upper part of the building's elevator room frame, and includes vertical members provided at the four corners to be spaced apart from each other, a lower horizontal member connecting the lower ends of adjacent vertical members, and a upper horizontal member connecting the upper ends of adjacent vertical members. A lower modular unit composed of an upper horizontal member and installed on the upper part of the elevator room frame; The upper part is constructed by stacking on top of the lower modular unit, consisting of vertical members provided at four corners to be spaced apart from each other, a lower horizontal member connecting the lower ends of neighboring vertical members, and an upper horizontal member connecting the upper ends of neighboring vertical members. modular unit; and a machine bed mounted on top of a pair of lower horizontal members facing each other of the upper modular unit. Consisting of, the lower modular unit and the upper modular unit are characterized in that they are mutually fixed by combining the upper horizontal member of the lower modular unit and the lower horizontal member of the upper modular unit with a plurality of coupling bolts.

Description

Modular structure for rooftop machinery room}

The present invention applies a modular system to the elevator machine room to shorten the construction period and improve constructability, and increases the bending rigidity by combining horizontal members with bonding bolts during stacking construction of the upper and lower modular units, thereby reducing the weight of the modular unit and efficiently handling the equipment load. It is about a modular structure for a rooftop machine room that can be supported.

In apartment buildings, the rooftop floor is connected to the staircase and elevator room. In particular, in the elevator room, a machine room for installing a traction machine or control panel for operating the elevator is located at the top of the elevator hall.

The rooftop machine room using the conventional reinforced concrete method is designed so that the load of the hoisting machine is supported by the slab and transmitted to the rooftop wall. However, because the load caused by the hoisting machine is significant, the slab is designed based on a load of 1.5 tons/㎡. Therefore, there is a problem that the slab thickness becomes excessively thick.

In addition, after pouring the machine room slab concrete through wet construction, the concrete hardens and then the support beam and machine bed for machine room equipment installation must be installed, which requires a lot of air.

Meanwhile, since the floor plan of each household floor in an apartment complex is maintained the same, repeated construction is possible for each floor using large forms such as gang form.

In contrast, the rooftop floor above the core where the staircase and elevator room are located has a different plan shape from the lower unit, making construction using large forms difficult. Accordingly, it is common to construct using a reinforced concrete method using conventional formwork such as Euroform.

However, conventional construction methods are highly dependent on manpower and are greatly influenced by site conditions, making it difficult to secure frame quality. In addition, since the rooftop floor is constructed at the end of the frame construction, the supply of on-site manpower and materials is not smooth, and a lot of air is required compared to the construction volume, so there is a risk of construction delays.

Therefore, the application of modular systems to rooftop structure construction is increasing recently.

Unlike existing buildings where the frame is constructed on site, the modular system is a construction system that is completed by stacking modular units pre-fabricated in a factory in a box-type form and assembling them up, down, left, and right on site.

In this modular system, most processes such as framing as well as various interior materials, mechanical equipment, and electrical wiring are carried out in factories. Therefore, excellent quality can be secured and construction period can be greatly shortened.

However, when constructing a machine room using a modular system, if the floor slab is configured to support the equipment load in the same way as the conventional construction method, the thickness of the floor slab becomes excessively thick, which increases the self-weight of the modular unit and increases the lifting burden. .

In addition, in the modular system, each member is mainly made of lightweight steel to reduce weight, but lightweight steel has limitations in structural performance, making it difficult for the horizontal members of the modular unit to directly support the machine room floor slab, which is subject to high loads.

KR 10-2021-0068283 A

In order to solve the above problems, the present invention applies a modular system to the elevator machine room to shorten the construction period and improve constructability, and to provide a rooftop machine room modular structure that can efficiently support the equipment load while lightweighting the modular unit. .

The present invention according to a preferred embodiment relates to a rooftop machine room modular structure installed on the upper part of the building elevator room frame, including vertical members provided at four corners to be spaced apart from each other, lower horizontal members connecting the lower ends of adjacent vertical members, and adjacent vertical members. A lower modular unit installed on the upper part of the elevator room frame and consisting of an upper horizontal member connecting the upper ends of the vertical members; The upper part is constructed by stacking on top of the lower modular unit, consisting of vertical members provided at four corners to be spaced apart from each other, a lower horizontal member connecting the lower ends of neighboring vertical members, and an upper horizontal member connecting the upper ends of neighboring vertical members. modular unit; and a machine bed mounted on top of a pair of lower horizontal members facing each other of the upper modular unit. It provides a rooftop machine room modular structure, wherein the lower modular unit and the upper modular unit are mutually fixed by combining the upper horizontal member of the lower modular unit and the lower horizontal member of the upper modular unit with a plurality of coupling bolts. .

The present invention according to another preferred embodiment provides a rooftop machine room modular structure, wherein the upper horizontal member and the lower horizontal member of the lower modular unit and the upper modular unit have a U-shaped cross section with an open inside.

The present invention according to another preferred embodiment provides a rooftop machine room modular structure, characterized in that a fire-resistant slab is provided inside the four lower horizontal members of the upper modular unit, each end of which is accommodated inside the lower horizontal members.

The present invention according to another preferred embodiment provides a rooftop machine room modular structure, characterized in that a lateral support beam is provided between a pair of upper horizontal members facing each other in the lower modular unit.

The present invention according to another preferred embodiment provides a rooftop machine room modular structure, characterized in that a fire-resistant slab is provided inside the four upper horizontal members of the lower modular unit, each end of which is accommodated inside the upper horizontal members.

The present invention according to another preferred embodiment is characterized in that the base beam is mounted on the upper part of the pair of lower horizontal members facing each other in the upper modular unit, and the machine bed is mounted on the upper part of the pair of facing base beams. Provides a rooftop machine room modular structure.

The present invention according to another preferred embodiment provides a rooftop machine room modular structure, characterized in that a lateral support beam is provided between a pair of upper horizontal members facing each other in the upper modular unit.

According to the present invention, the following effects are achieved.

First, when constructing elevator machine rooms of various structures, it is possible to provide a rooftop machine room modular structure that can shorten the construction period and improve constructability by stacking the upper and lower modular units.

Second, by mounting the machine bed on the horizontal members of the upper and lower modular units rather than the floor slab, the high load of the traction machine is directly transmitted to the frames of the horizontal members and vertical members, thereby reducing the load burden on the floor slab and thus minimizing the slab thickness. there is.

Third, the upper horizontal member of the lower modular unit and the lower horizontal member of the upper modular unit can be structurally integrated against bending by combining them with coupling bolts. Therefore, the bending rigidity of the interconnected horizontal members increases significantly, so the equipment load can be efficiently supported and transmitted to the vertical members without increasing the cross-section of the horizontal members.

Fourth, when the machine bed on which the equipment will be installed is placed on the upper part of the pair of lower horizontal members facing the upper modular unit and fixed with a connecting bolt, the machine bed can exhibit greater bending rigidity because it behaves as one with the horizontal member. The cross section can be minimized. As a result, the lifting burden is reduced by lightweighting the members, and it is economical due to the reduction in the amount of steel required.

Figure 1 is a perspective view showing a lower modular unit according to the first embodiment.
Figure 2 is a perspective view showing an upper modular unit according to the first embodiment.
Figure 3 is a perspective view showing a rooftop machine room modular structure according to the first embodiment.
Figure 4 is a perspective view showing upper and lower horizontal members joined by coupling bolts.
Figure 5 is a cross-sectional view showing the joint portion of the upper and lower modular units according to the first embodiment.
Figure 6 is a perspective view showing a lower modular unit according to the second embodiment.
Figure 7 is a perspective view showing an upper modular unit according to the second embodiment.
Figure 8 is a perspective view showing a rooftop machine room modular structure according to the second embodiment.
Figure 9 is a cross-sectional view showing the joint portion of the upper and lower modular units according to the second embodiment.

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

Figure 1 is a perspective view showing a lower modular unit according to the first embodiment, Figure 2 is a perspective view showing an upper modular unit according to the first embodiment, and Figure 3 is a rooftop machine room modular structure according to the first embodiment. It is a perspective view showing. And Figure 4 is a perspective view showing the upper and lower horizontal members joined by coupling bolts.

As shown in Figures 1 to 4, etc., the present invention relates to a rooftop machine room modular structure installed on the upper part of the building elevator room frame (1), which includes vertical members (21) provided at four corners to be spaced apart from each other, and neighboring The lower part is installed at the top of the elevator room frame (1) and consists of a lower horizontal member (22) connecting the lower end of the vertical member (21) and an upper horizontal member (23) connecting the upper end of the neighboring vertical member (21). Modular unit (2); Vertical members 31 provided at four corners to be spaced apart from each other, a lower horizontal member 32 connecting the lower ends of neighboring vertical members 31, and an upper horizontal member 33 connecting the upper ends of neighboring vertical members 31. ) and an upper modular unit (3) constructed by stacking on top of the lower modular unit (2); and a machine bed (4) mounted on top of a pair of lower horizontal members (32) facing each other of the upper modular unit (3); It consists of the lower modular unit (2) and the upper modular unit (3) combining the upper horizontal member (23) of the lower modular unit (2) and the lower horizontal member (32) of the upper modular unit (3) with a plurality of combinations. It is characterized by being mutually fixed by combining with bolts (5).

The present invention is to apply a modular system to an elevator machine room to shorten construction period and improve constructability, and to provide a rooftop machine room modular structure that can efficiently support the equipment load while lightweighting the modular unit.

The present invention can be applied not only to apartment complexes, but also to various buildings such as school facilities with rooftop floors, various lodging facilities, and officetels.

The rooftop machine room modular structure of the present invention is installed on the upper part of the building elevator room frame (1).

The lower elevator room frame (1) may be composed of various structural types, such as reinforced concrete or steel frame.

The rooftop machine room modular structure is constructed by stacking a lower modular unit (2) and an upper modular unit (3).

The lower modular unit (2) is constructed on the upper part of the elevator room frame (1) so that the elevator room and the internal space communicate with each other. That is, the lower modular unit 2 is in communication with the elevator room to secure the elevator overhead space.

The upper modular unit 3 is a space where equipment for operating an elevator, such as a traction machine or a control panel, is installed, and is constructed by stacking on top of the lower modular unit 2.

The lower modular unit (2) and the upper modular unit (3) each have vertical members (21, 31) provided at four corners to be spaced apart from each other, and lower parts that connect the lower and upper parts of neighboring vertical members (21, 31), respectively. It is composed of horizontal members (22, 32) and upper horizontal members (23, 33) and is formed as a whole into a rectangular parallelepiped shape.

The vertical members 21 and 31, lower horizontal members 22 and 32, and upper horizontal members 23 and 33 may each be made of lightweight steel.

A machine bed 4 on which equipment will be installed is mounted on the upper part of the pair of lower horizontal members 32 facing each other of the upper modular unit 3 (FIG. 2).

When the upper and lower modular units 2 and 3 are stacked, the upper horizontal member 23 of the lower modular unit 2 and the lower horizontal member 32 of the upper modular unit 3 are adjacent to each other vertically.

At this time, when the upper horizontal member 23 and the lower horizontal member 32 of the same cross-section are not joined to each other but are separated and simply brought into close contact, each member bends individually based on the neutral axis of each member in response to the upper load. . Therefore, the secondary moment of inertia due to the entire cross section of the two members is simply the sum of the secondary moments of inertia of each member.

Furthermore, when the upper horizontal member 23 and the lower horizontal member 32 are spaced apart from each other for fire-resistant coating or joining the upper and lower parts of the vertical members 21 and 31, the lower horizontal member 32 of the upper modular unit 3 ) is not transmitted at all to the upper horizontal member (23) of the lower modular unit (2), so the lower horizontal member (32) of the upper modular unit (3) must support it alone. Accordingly, there is a problem in that the cross section of the lower horizontal member 32 becomes excessively large to support the equipment load.

Therefore, the lower modular unit 2 and the upper modular unit 3 are connected to the upper horizontal member 23 of the lower modular unit 2 and the lower horizontal member 32 of the upper modular unit 3 by a plurality of coupling bolts (5). ), the upper horizontal member 23 of the lower modular unit 2 and the lower horizontal member 32 of the upper modular unit 3 can be structurally integrated against bending by the shear force of the coupling bolt 5. You can.

When the joint surface of the upper horizontal member 23 and the lower horizontal member 32 is fixed with the coupling bolt 5, the two members behave relative to one neutral axis against bending due to the shear force of the coupling bolt 5. I do it. Therefore, the height of all members becomes twice the height of each member, and the secondary moment of inertia of the overall cross section becomes 8 times the size of the secondary moment of inertia of each member.

As a result, the shear stress of the joint surface of the two members results in much greater bending rigidity than that of the individual horizontal members 23 and 32.

Accordingly, the bending rigidity of the horizontal members (23, 32) bonded to each other in the state where the upper and lower two modular units (2, 3) are stacked increases significantly, so that the equipment load can be increased without increasing the cross-section of the horizontal members (23, 32). It can be sufficiently supported and transmitted to the vertical members (21, 31).

The coupling bolts 5 can be designed to have an appropriate cross section and number to sufficiently exert shear stress due to bending between the horizontal members 23 and 32 to be joined.

A plurality of coupling bolts 5 are installed to be spaced apart from each other in the longitudinal direction of the horizontal members 23 and 32. Since the horizontal members 23 and 32 are formed to be relatively long, they can be configured to exert sufficient shear force by installing the required number of coupling bolts 5 at any point.

Unlike the existing modular system in which the vertical members (21, 31) were mainly joined when joining the upper and lower modular units (2, 3) and the horizontal members (23, 32) were separated from each other, the present invention uses the horizontal members (23, 32) ) are joined to integrate each other, so vibration or deflection of the horizontal members 23 and 32 can be minimized.

The machine bed 4 can also be fixedly coupled to the upper surface of the lower horizontal member 32 of the upper modular unit 3 by a plurality of coupling bolts 5 while being in close contact with the upper surface.

Anti-vibration rubber 41 can be installed between the machine bed 4 and the lower horizontal member 32 to reduce equipment vibration (FIG. 5).

In this case, the machine bed 4 as a whole also moves integrally with the horizontal members 23 and 32, so it can exhibit greater bending rigidity, and thus the cross-sectional size of the horizontal members 23 and 32 can be minimized. Therefore, the lifting burden is reduced by lightweighting the member, and cost savings are possible by reducing the amount of steel required.

The machine bed (4) can be brought in and installed after installation of the upper modular unit (3).

Alternatively, if the lifting burden of the machine bed (4) is not large, the machine bed (4) can be manufactured as an integrated unit during factory manufacturing of the upper modular unit (3), thereby significantly saving on-site construction time.

As shown in Figure 4, etc., the upper horizontal members (23, 33) and lower horizontal members (22, 32) of the lower modular unit (2) and upper modular unit (3) are composed of a U-shaped cross section with an open inside. can do.

After stacking the upper modular unit (3) on top of the lower modular unit (2), the horizontal members (23, 32) at the joint must be fastened with coupling bolts (5). At this time, in order to facilitate fastening of the coupling bolts 5, each of the upper horizontal members 23 and 33 and the lower horizontal members 22 and 32 may be formed in a U-shaped cross section with an open inside.

A U-shaped channel with one side open allows the web to be eccentrically arranged on the outside to secure sufficient space inside. In addition, since there is no interference from the web, the fastening position of the coupling bolt (5) can be freely set.

Figure 5 is a cross-sectional view showing the joint portion of the upper and lower modular units according to the first embodiment.

As shown in Figures 2 and 5, inside the four lower horizontal members 32 in the upper modular unit 3, there is a fireproof slab 34, each end of which is accommodated inside the lower horizontal members 32. It can be provided.

Since the modular unit that forms the elevator machine room with a modular system is a major structural member, it must be constructed with a fire-resistant structure that can withstand a fire for more than 3 hours. Therefore, in order to form the elevator machine room into a fireproof structure, the fireproof slab 34 can be installed inside the lower horizontal member 32 of the upper modular unit 3.

The fireproof slab 34 can be made of concrete or non-shrinkage mortar with a thickness of 100 mm or more. If a slab with a thickness of 100 mm or more is formed with concrete or non-shrinking mortar, it can be recognized as a fire-resistant structure without a separate fire resistance test.

Since the lower horizontal members 32 are formed in a U-shaped cross section with an open inside, the end of the fireproof slab 34 is inserted into the inside of the lower horizontal member 32 through the open inside to form the lower horizontal member 32. It can be mounted on the upper surface of the lower flange.

When the fire-resistant slab (34) is mounted on top of the lower horizontal members (32), floor height loss occurs as much as the thickness of the fire-resistant slab (34). However, if the fire-resistant slab 34 is placed between the lower horizontal members 32, there is no loss in floor height, and the height of the entire modular unit can be minimized.

As described above, in the present invention, the horizontal members 23 and 32, which are structural elements supporting the equipment load, and the fire-resistant slab 34, which is a fire-resistant element, can be constructed separately. As a result, the cross-sectional size of the horizontal members 23 and 32 as well as the thickness of the floor slab can be reduced, making it possible to reduce the weight of the modular unit and reduce costs by reducing the quantity.

The fire-resistant slab 34 not only serves as a fire-resistant member but also serves as a stepping stone for workers when installing machine room equipment.

In addition, the fireproof slab 34 serves as a diaphragm of a square frame composed of the lower horizontal member 32, so resistance to lateral force can be improved.

Meanwhile, when a fireproof slab 34 is provided between the lower horizontal members 32 of the upper modular unit 3, it may be difficult to fasten the coupling bolts 5 due to interference of the fireproof slab 34.

Accordingly, the coupler 7 can be embedded in advance to fasten the coupling bolt 5 inside the fireproof slab 34 (FIG. 5).

Alternatively, a box-out may be formed in the refractory slab 34 at the area where the coupling bolts 5 are fastened, and the box-out may be filled with non-shrink mortar after fastening the coupling bolts 5.

When the upper horizontal member 23 of the lower modular unit 2 and the lower horizontal member 32 of the upper modular unit 3 are spaced apart from each other, a spacer 6 may be installed between the upper and lower horizontal members 23 and 32. You can. When the coupling bolt 5 is tightened, the upper and lower horizontal members 32 can be supported without being deformed by the spacer 6.

As shown in FIGS. 1 and 5, a transverse support beam 25 may be provided between a pair of upper horizontal members 23 facing each other in the lower modular unit 2.

In the present invention, the equipment load is supported by the joined horizontal members (23, 32), and the fireproof slab (34) installed in the upper modular unit (3) only needs to form a fireproof structure.

Therefore, there is no need to install a separate slab on the ceiling of the lower modular unit (2). In this case, the upper horizontal members 23 of the lower modular unit 2 are not separately supported laterally, so the upper horizontal members 23 may be deformed during lifting.

Therefore, the transverse support beam 25 can be installed as a transverse support element between the pair of upper horizontal members 23 facing each other of the lower modular unit 2.

For this purpose, a gusset plate 250 can be coupled to the inside of the upper horizontal member 23 (FIG. 5). That is, the gusset plate 250 protruding inside the upper horizontal member 23 can be coupled, and each end of the transverse support beam 25 can be fixed to the gusset plates 250 on both sides.

Figure 6 is a perspective view showing the lower modular unit according to the second embodiment, Figure 7 is a perspective view showing the upper modular unit according to the second embodiment, and Figure 8 is a rooftop machine room modular structure according to the second embodiment. It is a perspective view showing.

As shown in FIG. 6, etc., a fireproof slab 24 may be provided inside the four upper horizontal members 23 in the lower modular unit 2, each end of which is accommodated inside the upper horizontal member 23. there is.

The fireproof slab (24) may be installed in the lower modular unit (2) instead of being installed in the upper modular unit (3).

Since the fireproof slab 24 serves as a lateral support element, there is no need to install a separate lateral support beam 25 on the upper part of the lower modular unit 2. Accordingly, it is possible to reduce the amount of steel structure.

The thickness of the fire-resistant slab (24) is smaller than the gap between the upper and lower flanges of the upper horizontal member (23), and the fire-resistant slab (24) is mounted on the upper part of the lower flange of the upper horizontal member (23) to separate the upper and upper surfaces of the fire-resistant slab (24). When the lower surfaces of the upper flanges of the horizontal member 23 are spaced apart, the coupling bolt 5 can be fastened through the spaced space.

As shown in FIGS. 2 and 7, a transverse support beam 35 may be provided between a pair of upper horizontal members 33 facing each other in the upper modular unit 3.

There is no need to install a separate fireproof member on the ceiling of the upper modular unit 3. However, in this case, the upper horizontal member 33 may be deformed when the upper modular unit 3 is lifted, so a lateral support beam 35 is installed between a pair of facing upper horizontal members 33 to serve as a lateral support element. You can use it.

In addition, in order to install equipment such as a traction machine on the upper part of the machine bed (4), small lifting equipment such as a chain block must be fixedly installed at the lower part of the machine room ceiling. Accordingly, previously, lifting hooks for hanging lifting equipment were embedded inside the ceiling slab in advance. However, since the lifting hook protrudes from the lower part of the ceiling slab, it interferes with the formwork, making installation cumbersome.

Therefore, by using the lateral support beam 35 coupled to the upper horizontal member 33 of the upper modular unit 3 as a beam for fixing the hook of the lifting equipment, the work of embedding the lifting hook can be omitted.

Figure 9 is a cross-sectional view showing the joint portion of the upper and lower modular units according to the second embodiment.

As shown in FIGS. 7 and 9, a base beam 36 is mounted on the upper part of the pair of lower horizontal members 32 facing each other in the upper modular unit 3, and the machine bed 4 faces each other. It can be mounted on the upper part of a pair of base beams (36).

Modular units are constructed by personnel from steel or framing companies as part of the construction process. In contrast, machine beds are generally manufactured by elevator machine manufacturers and even installed on site.

Therefore, the modular unit installation process and the machine bed installation process can be performed separately. At this time, if the details of the joint between the machine bed and the horizontal member are not accurate, difficulties may arise in field installation of the machine bed (4).

Therefore, the base beam 36 can be installed on the upper part of the lower horizontal member 32 of the upper modular unit 3, and the machine bed 4 can be mounted and fixed on the upper part of the base beam 36.

For this purpose, fastening holes are formed in the upper flange of the base beam 36 for connection with the machine bed 4, and fastening holes are formed in the lower flange of the base beam 36 for connection with the lower horizontal member 32. It can be.

The installation position of the machine bed 4 can be appropriately adjusted by the base beam 36.

In addition, the base beam 36 is the lower horizontal member of the upper modular unit 3, similar to the joint between the upper horizontal member 23 of the lower modular unit 2 and the lower horizontal member 32 of the upper modular unit 3 ( 32) It can be mutually fixed by the upper flange and a plurality of coupling bolts (5).

Therefore, the bending rigidity is greatly increased for the triple structure of the upper horizontal member 23 of the lower modular unit 2, the lower horizontal member 32 and the base beam 36 of the upper modular unit 3.

1: Elevator room framework
2: Lower modular unit
21: Vertical member
22: Lower horizontal member
23: Upper horizontal member
24: Fireproof slab
25: Lateral support beam
250: Gusset plate
3: Upper modular unit
31: Vertical member
32: Lower horizontal member
33: Upper horizontal member
34: Fireproof slab
35: Transverse support beam
36: base beam
4: Machine bed
41: Anti-vibration rubber
5: Combined bolt
6: spacer
7: Coupler

Claims (7)

It relates to a rooftop machine room modular structure installed on the upper part of the building elevator room frame (1),
Vertical members 21 provided at four corners to be spaced apart from each other, a lower horizontal member 22 connecting the lower ends of neighboring vertical members 21, and an upper horizontal member 23 connecting the upper ends of neighboring vertical members 21. ) and a lower modular unit (2) installed on the upper part of the elevator room frame (1);
Vertical members 31 provided at four corners to be spaced apart from each other, a lower horizontal member 32 connecting the lower ends of neighboring vertical members 31, and an upper horizontal member 33 connecting the upper ends of neighboring vertical members 31. ) and an upper modular unit (3) constructed by stacking on top of the lower modular unit (2); and
A machine bed (4) mounted on top of a pair of lower horizontal members (32) facing each other of the upper modular unit (3); It consists of,
The lower modular unit (2) and the upper modular unit (3) connect the upper horizontal member (23) of the lower modular unit (2) and the lower horizontal member (32) of the upper modular unit (3) with a plurality of coupling bolts (5). A rooftop machine room modular structure characterized in that it is connected and fixed to each other.
In paragraph 1:
The upper horizontal members (23, 33) and lower horizontal members (22, 32) of the lower modular unit (2) and upper modular unit (3) are a rooftop machine room modular structure, characterized in that the inner side is open and has a U-shaped cross section.
In paragraph 2,
A rooftop machine room modular structure, characterized in that a fireproof slab (34) is provided inside the four lower horizontal members (32) of the upper modular unit (3), each end of which is accommodated inside the lower horizontal members (32).
In paragraph 3,
A rooftop machine room modular structure, characterized in that a lateral support beam (25) is provided between a pair of upper horizontal members (23) facing each other in the lower modular unit (2).
In paragraph 2,
A rooftop machine room modular structure, characterized in that a fire-resistant slab (24) is provided inside the four upper horizontal members (23) of the lower modular unit (2), each end of which is accommodated inside the upper horizontal members (23).
In paragraph 1:
A base beam (36) is mounted on each of the pair of lower horizontal members (32) facing each other in the upper modular unit (3), and the machine bed (4) is mounted on the top of the pair of base beams (36) facing each other. A rooftop machine room modular structure characterized by being mounted.
In paragraph 1:
A rooftop machine room modular structure, characterized in that a lateral support beam (35) is provided between a pair of upper horizontal members (33) facing each other in the upper modular unit (3).

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