CN113572094A - Line pipeline interchange integrated bridge and wiring method thereof - Google Patents

Abstract

The invention relates to the technical field of bridges, in particular to a line pipeline interchange integrated bridge, which comprises a first layer of bridge and a second layer of bridge, wherein a first layer of main four channels and a first layer of auxiliary four channels are arranged on the first layer of bridge, a second layer of main four channels is arranged on the second layer of bridge, and a first avoidance channel which is communicated with the first layer of auxiliary four channels and transversely avoids the first layer of main four channels is arranged at the intersection of the first layer of main four channels and the first layer of auxiliary four channels. The invention also discloses a wiring method of the line pipeline interchange integrated bridge. The line pipeline interchange integrated bridge frame and the wiring method thereof provided by the invention have simple structures, not only ensure that all channels are not interfered with each other and meet the specified space requirement, but also improve the space utilization rate, save the installation space and meet the requirement of the net height of a suspended ceiling through avoiding and penetrating arrangement between two layers of bridge frames compared with the traditional arrangement structure which is overlapped layer by layer.

Description

Line pipeline interchange integrated bridge and wiring method thereof

[ technical field ] A method for producing a semiconductor device

The invention relates to the technical field of bridges, in particular to a line pipeline interchange integrated bridge and a wiring method thereof.

[ background of the invention ]

When in building construction, the line pipeline layout is often required to be carried out by building a bridge, particularly for buildings with more pipelines such as hospitals and the like, the method is to lay a plurality of professional bridges, such as informatization bridges, automation bridges, weak current power supply bridges, operator bridges and the like, wherein all bridges are not interfered with each other, the bridges are generally arranged in a layer-by-layer overlapping way in the traditional method, but the four-way position pipeline is complex, the occupied space is large due to the layer-by-layer overlapping arrangement, the net height requirement of the suspended ceiling of the hospital is difficult to meet, and under the condition that the plurality of bridges are arranged on the walkways, the crossed positions of the bend, the tee joint and the cross joint can not avoid the space tension and can not meet the specified space requirement, meanwhile, the installation operation difficulty of installation personnel is increased, the labor loss is reduced, the time cost is high, the crossed position is not beneficial to the installation and fixation of the support, and the maintenance in the later period of the threading stay wire is difficult.

[ summary of the invention ]

The invention aims to provide a line pipeline interchange integrated bridge and a wiring method thereof, and solves the problem that the net height requirement of a suspended ceiling cannot be met due to the fact that the traditional layer-by-layer layout mode occupies large space in the prior art.

In order to solve the above problems, the present invention provides the following technical solutions:

the line pipeline interchange integrated bridge comprises a first layer of bridge and a second layer of bridge, wherein a first layer of main four channels and a first layer of auxiliary four channels are arranged on the first layer of bridge, a second layer of main four channels are arranged on the second layer of bridge, and a first avoidance channel which is communicated with the first layer of auxiliary four channels and stretches across the first layer of main four channels on the second layer of bridge to avoid the first layer of main four channels is arranged at the intersection of the first layer of main four channels and the first layer of auxiliary four channels.

The line pipeline interchange integrated bridge frame is characterized in that a second layer of auxiliary four channels are arranged on the second layer of bridge frame, and a second avoidance channel which is communicated with the second layer of auxiliary four channels and transversely avoids the second layer of main four channels on the first layer of bridge frame is arranged at the intersection of the second layer of auxiliary four channels and the second layer of main four channels.

The line pipeline interchange integrated bridge frame comprises a first layer of main four channels, a second layer of auxiliary four channels, a third layer of auxiliary four channels, a fourth layer of auxiliary four channels and a fourth layer of auxiliary four channels, wherein two adjacent channels of the first layer of auxiliary four channels are respectively intersected with two adjacent channels of the first layer of main four channels, and the four channels are encircled to form a first layer of bridge frame cavity; two adjacent channels of the second layer of auxiliary four channels are respectively intersected with two adjacent channels of the second layer of main four channels, and the four channels are surrounded to form a second layer of bridge cavity; the second layer of main four channels are arranged on the first layer of bridge frame and are positioned at the position opposite to the cavity of the first layer of bridge frame, and the first layer of auxiliary four channels are arranged on the second layer of bridge frame and are positioned at the position opposite to the cavity of the second layer of bridge frame.

The line pipeline interchange integrated bridge frame is characterized in that a third avoidance channel which crosses over the first layer of main four channels to avoid the first layer of main four channels is further arranged on the second layer of bridge frame, and the third avoidance channel is communicated with the second avoidance channel, so that the third avoidance channel is communicated with the second layer of auxiliary four channels, and the second layer of auxiliary four channels are respectively not interfered with the first layer of main four channels and the second layer of main four channels.

The line pipeline interchange integrated bridge frame is characterized in that the first avoidance channel is provided with a first avoidance channel through hole for communicating the first layer of auxiliary four channels, and the first avoidance channel through hole is positioned at the intersection of the first avoidance channel and the second layer of main four channels; a third avoidance channel through hole for communicating with a second avoidance channel is formed in the third avoidance channel, and the third avoidance channel through hole is located at the intersection of the third avoidance channel and the second layer of main four channels; and a second layer of auxiliary four-channel through hole for communicating the second avoidance channel is formed in the second layer of auxiliary four-channel and is positioned at the intersection of the second layer of auxiliary four-channel and the second layer of main four-channel.

The line pipeline interchange integrated bridge frame is characterized in that the first avoidance channel through hole, the third avoidance channel through hole and the second layer of auxiliary four-channel through hole are all internally provided with buffer gaskets.

The line pipeline interchange integrated bridge frame is characterized in that a spacing groove is arranged between the third avoidance channel and the first avoidance channel.

The line pipeline interchange integrated bridge frame is characterized in that chamfers are arranged between two adjacent channels of the first layer of main four channels, between two adjacent channels of the first layer of auxiliary four channels, between two adjacent channels of the second layer of main four channels and between two adjacent channels of the second layer of auxiliary four channels.

The method for wiring the line pipeline interchange integrated bridge frame comprises the following steps:

a first group of circuit pipes are arranged in the first layer of main four channels along the four-way direction;

a second group of circuit pipes are arranged in the second layer of main four channels along the four-way direction;

and arranging a third group of line pipes in the first layer of auxiliary four channels along the four-way direction, and penetrating the third group of line pipes into a first avoidance channel which spans and avoids the first layer of main four channels at the intersection of the first layer of main four channels and the first layer of auxiliary four channels to avoid the first group of line pipes.

Compared with the prior art, the invention has the following advantages:

1. the line pipeline interchange integrated bridge frame and the wiring method thereof provided by the invention have simple structures, and the first avoidance channel is arranged on the second layer of bridge frame, so that the first layer of main four channels can be bypassed by the first avoidance channel at the intersection of the first layer of auxiliary four channels on the first layer of bridge frame and the first layer of main four channels, the first layer of auxiliary four channels and the second layer of main four channels are not interfered with each other, and the specified space requirement is met.

2. The line pipeline interchange integrated bridge frame provided by the invention is low in installation difficulty and high in installation efficiency, is beneficial to installation and fixation of a support, is convenient for later maintenance of a stay wire, and can reduce bending of other pipelines and save cost.

[ description of the drawings ]

Fig. 1 is a first schematic structural diagram according to an embodiment of the present invention.

Fig. 2 is a second schematic structural diagram according to an embodiment of the present invention.

Fig. 3 is an exploded view of an embodiment of the present invention.

FIG. 4 is a schematic wiring diagram according to an embodiment of the present invention.

[ detailed description ] embodiments

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, belong to the scope of the present invention.

Referring to fig. 1 to 4, the present embodiment provides a line pipeline overpass integrated bridge, including a first layer of bridge 1 and a second layer of bridge 2, where the first layer of bridge 1 is provided with a first layer of main four channels 11 and a first layer of auxiliary four channels 12, the second layer of bridge 2 is provided with a second layer of main four channels 21, and a first avoidance channel 23, which is communicated with the first layer of auxiliary four channels 12 and crosses the second layer of bridge 2 to avoid the first layer of main four channels 11, is disposed at an intersection of the first layer of main four channels 11 and the first layer of auxiliary four channels 12. The line pipeline interchange integrated bridge frame provided by the embodiment is simple in structure, the first avoidance channel 23 is arranged on the second layer of bridge frame 2, so that the first layer main four channel 11 can be bypassed by the first avoidance channel 23 at the intersection of the first layer auxiliary four channel 12 on the first layer of bridge frame 1 and the first layer main four channel 11, the first layer auxiliary four channel 12 and the second layer main four channel 21 are not interfered with each other, and the specified space requirement is met; moreover, the installation difficulty of this embodiment is low, and the installation effectiveness is high, is favorable to the installation of support fixed, is convenient for wear the maintenance in stay wire later stage, can reduce other pipelines simultaneously and turn over curved, practices thrift the cost.

Further, a second layer of auxiliary four channels 22 are arranged on the second layer of bridge 2, and a second avoidance channel 13 which is communicated with the second layer of auxiliary four channels 22 and spans the second layer of main four channels 21 on the first layer of bridge 1 to avoid the second layer of main four channels 21 is arranged at the intersection of the second layer of auxiliary four channels 22 and the second layer of main four channels 21. In this embodiment, four channels of the first layer main four channels 11 in the first layer bridge 1 all penetrate through the first layer bridge 1, four channels of the second layer main four channels 21 in the second layer bridge 2 all penetrate through the second layer bridge 2, and two adjacent channels, which are intersected with the first layer main four channels 11, in the first layer sub-four channels 12 in the first layer bridge 1 are communicated with the first avoidance channel 23 in the second layer bridge 2 to avoid the first layer main four channels 11; two adjacent channels in the second layer of auxiliary four channels 22 in the second layer of bridge frame 2, which are crossed with the second layer of main four channels 21, are communicated with the second avoidance channel 13 in the first layer of bridge frame 1 to avoid the second layer of main four channels 21; the four channels are arranged only by two layers of bridging, and compared with the traditional layer-by-layer stacking arrangement mode, the four-channel ceiling structure greatly reduces the space occupation, improves the clear height of the space utilization rate and meets the clear height requirement of the suspended ceiling; and two-layer crane span structure compares in multilayer crane span structure, and construction convenience, the wiring is easy, and construction cost is lower, and the installation effectiveness is higher, has reduced the use of turning over curved simultaneously, has reduced the construction degree of difficulty.

Further, two adjacent channels of the first layer of secondary four channels 12 are respectively intersected with two adjacent channels of the first layer of main four channels 11, and the four channels surround to form a first layer of bridge cavity 14; two adjacent channels of the second layer of auxiliary four channels 22 are respectively intersected with two adjacent channels of the second layer of main four channels 21, and the four channels surround to form a second layer of bridge cavity 24; the second layer of main four channels 21 is disposed on the first layer of bridge 1 opposite the first layer of bridge cavities 14, and the first layer of auxiliary four channels 12 is disposed on the second layer of bridge 2 opposite the second layer of bridge cavities 24. By adopting the structure, the middle pivot positions of the four channels of the first layer main four channel 11, the first layer auxiliary four channel 12, the second layer main four channel 21 and the second layer auxiliary four channel 22 are not overlapped in space, so that mutual interference among the four channels is effectively avoided, the specified spacing requirement is met, and meanwhile, the four channels are closely arranged in space, so that the space is more compact, and the space utilization rate is improved.

Further, a third avoidance channel 25 which straddles the first layer main four-channel 11 is further arranged on the second layer bridge 2, and the third avoidance channel 25 is communicated with the second avoidance channel 13, so that the second layer auxiliary four-channel 22 is communicated with the second layer main four-channel 11 and the second layer main four-channel 21, and the second layer auxiliary four-channel 22 is not interfered with each other. The interference between the second layer auxiliary four-channel 22 and the first layer main four-channel 11 and the second layer main four-channel 21 can be effectively avoided, the structure is simple, and the construction is convenient.

Further, a first avoidance channel through hole 231 for communicating with the first layer of sub-four channels 12 is formed in the first avoidance channel 23, and the first avoidance channel through hole 231 is located at the intersection of the first avoidance channel 23 and the second layer of main four channels 21; a third avoidance channel through hole 251 for communicating the second avoidance channel 13 is formed in the third avoidance channel 25, and the third avoidance channel through hole 251 is located at the intersection of the third avoidance channel 25 and the second layer main four-channel 21; and a second layer sub four-channel through hole 221 for communicating the second avoidance channel 13 is formed in the second layer sub four-channel 22, and the second layer sub four-channel through hole 221 is positioned at the intersection of the second layer sub four-channel 22 and the second layer main four-channel 21. Through first dodging passageway through-hole 231, the third dodges passageway through-hole 251 and the vice four passageway through-hole 221 in second floor realize the intercommunication so that realize alternating between second crane span structure 2 and first crane span structure 1 and dodge, simple structure, construction convenience, each through-hole lays the position exquisitely simultaneously, under the prerequisite of guaranteeing each four passageways noninterfere interference, utilizes the space to the utmost for overall structure is compacter orderly.

Further, cushion washers are disposed in the first avoidance channel through hole 231, the third avoidance channel through hole 251 and the second layer sub-four channel through hole 221. The buffer gasket that adopts in this embodiment is the rubber gasket, and the circuit cable is run into the both sides channel angle of through-hole and the fish tail damage when preventing to act as go-between when first layer crane span structure and second layer crane span structure interlude.

Further, a spacing groove 26 is arranged between the third avoidance channel 25 and the first avoidance channel 23. The space between the third avoidance channel 25 and the first avoidance channel 23 is ensured, and the mutual interference of the lines in the third avoidance channel 25 and the first avoidance channel 23 is avoided.

Furthermore, chamfers are arranged between two adjacent channels of the first layer of main four channels 11, between two adjacent channels of the first layer of auxiliary four channels 12, between two adjacent channels of the second layer of main four channels 21 and between two adjacent channels of the second layer of auxiliary four channels 22. The scratch-proof device is beneficial to avoiding damage of a circuit due to the fact that the circuit is in contact with the right-angle side of the joint of the two adjacent channels when passing through the joint of the two adjacent channels, is beneficial to increasing the area of a pivot region in the middle of the channel, and is convenient for wiring and later maintenance.

The embodiment also provides a method for wiring the integrated bridge of the line pipeline overpass, which comprises the following specific steps:

a first group of line pipes are arranged in the first layer of main four channels 11 along the four-way direction;

a second group of circuit pipes are arranged in the second layer of main four channels 21 along the four-way direction;

and arranging a third group of line pipes in the first layer of auxiliary four-way channels 12 along the four-way direction, and penetrating the third group of line pipes into a first avoidance channel 23 which crosses and avoids the first layer of main four-way channels 11 at the intersection of the first layer of main four-way channels 11 and the first layer of auxiliary four-way channels 12 to avoid the first group of line pipes. Compared with the traditional layer-by-layer overlapped layout mode, the line pipeline interchange integrated bridge frame layout method provided by the invention has the advantages that the space utilization rate is improved, the installation space is saved and the requirement on the net height of a suspended ceiling can be met by avoiding and inserting the two layers of bridge frames.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. Line pipeline overpass integration crane span structure, its characterized in that: including first layer crane span structure (1) and second floor crane span structure (2), be equipped with the vice four passageways (12) of first layer main four passageways (11) and first layer on first layer crane span structure (1), be equipped with the vice four passageways (21) of second layer main on second floor crane span structure (2), the vice four passageways (12) cross section of first layer main four passageways (11) and first layer be equipped with the vice four passageways (12) of first layer intercommunication and span in second floor crane span structure (2) and dodge first dodge passageway (23) of first layer main four passageways (11).

2. The line duct interchange integrated bridge frame of claim 1, wherein: and a second layer of auxiliary four channels (22) are arranged on the second layer of bridge (2), and a second avoidance channel (13) which is communicated with the second layer of auxiliary four channels (22) and spans the first layer of bridge (1) to avoid the second layer of main four channels (21) is arranged at the intersection of the second layer of auxiliary four channels (22) and the second layer of main four channels (21).

3. The line duct interchange integrated bridge frame of claim 2, wherein:

two adjacent channels of the first layer of auxiliary four channels (12) are respectively intersected with two adjacent channels of the first layer of main four channels (11), and the four channels surround to form a first layer of bridge cavity (14);

two adjacent channels of the second layer of auxiliary four channels (22) are respectively intersected with two adjacent channels of the second layer of main four channels (21), and the four channels surround to form a second layer of bridge cavity (24);

the second layer of main four channels (21) are arranged on the first layer of bridge (1) and are opposite to the first layer of bridge cavities (14), and the first layer of auxiliary four channels (12) are arranged on the second layer of bridge (2) and are opposite to the second layer of bridge cavities (24).

4. The line duct interchange integrated bridge frame of claim 3, wherein: and a third avoidance channel (25) which stretches across the second layer of bridge (2) to avoid the first layer of main four channels (11) is further arranged on the second layer of bridge (2), and the third avoidance channel (25) is communicated with the second avoidance channel (13) so as to be communicated with the second layer of auxiliary four channels (22), so that the second layer of auxiliary four channels (22) are not interfered with the first layer of main four channels (11) and the second layer of main four channels (21) respectively.

5. The line duct interchange integrated bridge frame of claim 4, wherein:

a first avoidance channel through hole (231) used for communicating a first layer of sub-four channels (12) is formed in the first avoidance channel (23), and the first avoidance channel through hole (231) is located at the intersection of the first avoidance channel (23) and a second layer of main four channels (21);

a third avoidance channel through hole (251) used for being communicated with a second avoidance channel (13) is formed in the third avoidance channel (25), and the third avoidance channel through hole (251) is located at the intersection of the third avoidance channel (25) and a second layer of main four channels (21);

and a second layer of auxiliary four-channel through hole (221) used for communicating the second avoidance channel (13) is formed in the second layer of auxiliary four-channel (22), and the second layer of auxiliary four-channel through hole (221) is located at the intersection of the second layer of auxiliary four-channel (22) and the second layer of main four-channel (21).

6. The line duct interchange integrated bridge frame of claim 5, wherein: and buffer gaskets are arranged in the first avoidance channel through hole (231), the third avoidance channel through hole (251) and the second layer of sub-four channel through hole (221).

7. The line duct interchange integrated bridge frame of claim 4, wherein: and a spacing groove (26) is arranged between the third avoidance channel (25) and the first avoidance channel (23).

8. The line duct interchange integrated bridge frame of claim 2, wherein: chamfers are arranged between two adjacent channels of the first layer of main four channels (11), between two adjacent channels of the first layer of auxiliary four channels (12), between two adjacent channels of the second layer of main four channels (21) and between two adjacent channels of the second layer of auxiliary four channels (22).

9. The method for wiring the line pipeline interchange integrated bridge is characterized by comprising the following steps of:

a first group of line pipes are arranged in the first layer of main four channels (11) along the four-way direction;

a second group of circuit pipes are arranged in the second layer of main four channels (21) along the four-way direction;

and a third group of line pipes are arranged in the first layer of auxiliary four channels (12) along the four-way direction, and the third group of line pipes penetrate into a first avoidance channel (23) which crosses and avoids the first layer of main four channels (11) to avoid the first group of line pipes at the intersection of the first layer of main four channels (11) and the first layer of auxiliary four channels (12).

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