阅读说明：本技术 一种仪表管路布置样法及热控仪表管路 (Instrument pipeline arrangement sample method and thermal control instrument pipeline ) 是由 黄强 薛潇 唐劲 刘小豪 谭红波 于 2021-09-06 设计创作，主要内容包括：本发明的实施例提供了一种仪表管路布置样法及热控仪表管路,涉及管路设计技术领域领域,其中,该仪表管路布置样法包括在仪表架上布置第一仪表管路,并对第一仪表管路弯制处理,以使第一弯制点和第二弯制点共同将第一仪表管路分隔为依次连接的第一管路、第二管路及第三管路,并在仪表架上布置第二仪表管路,对第二仪表管路弯制处理,以使第三弯制点和第四弯制点共同将第二仪表管路分隔为依次连接的第四管路、第五管路及第六管路,并通过此方法制作热控仪表管路,包括仪表架、第一仪表管路及第二仪表管路,通过此方法制作热控仪表管路,保证了施工工艺美观,形成统一规范的扇形仪表架,并且可以使得施工人员可以快速上手,提高了施工效率。(The embodiment of the invention provides an instrument pipeline arrangement method and a thermal control instrument pipeline, and relates to the technical field of pipeline design, wherein the instrument pipeline arrangement method comprises the steps of arranging a first instrument pipeline on an instrument frame, bending the first instrument pipeline to ensure that a first bending point and a second bending point jointly divide the first instrument pipeline into a first pipeline, a second pipeline and a third pipeline which are sequentially connected, arranging a second instrument pipeline on the instrument frame, bending the second instrument pipeline to ensure that the third bending point and the fourth bending point jointly divide the second instrument pipeline into a fourth pipeline, a fifth pipeline and a sixth pipeline which are sequentially connected, manufacturing the thermal control instrument pipeline by the method, comprising the instrument frame, the first instrument pipeline and the second instrument pipeline, manufacturing the thermal control instrument pipeline by the method, ensuring the construction process to be beautiful, the fan-shaped instrument rack with unified specification is formed, and constructors can quickly operate, so that the construction efficiency is improved.)

1. An instrument tube layout pattern method for arranging a plurality of instrument tubes, comprising:

arranging a first instrument pipeline on an instrument frame, bending the first instrument pipeline to enable the first instrument pipeline to form a first bending point and a second bending point, wherein the first bending point and the second bending point jointly divide the first instrument pipeline into a first pipeline, a second pipeline and a third pipeline which are connected in sequence;

arranging a second instrument pipeline on the instrument frame, and bending the second instrument pipeline to form a third bending point and a fourth bending point, wherein the third bending point and the fourth bending point jointly divide the second instrument pipeline into a fourth pipeline, a fifth pipeline and a sixth pipeline which are connected in sequence;

the second pipeline has a first preset point, a connecting line of the first preset point and the third bending point is perpendicular to the second pipeline, and the first preset point and the first bending point have the same height.

2. An instrument tube layout method according to claim 1, wherein:

sequentially arranging a plurality of third instrument pipelines, and sequentially bending the plurality of third instrument pipelines to form a fifth bending point and a sixth bending point on each third instrument pipeline, wherein the fifth bending point and the sixth bending point jointly divide the third instrument pipeline into a seventh pipeline, an eighth pipeline and a ninth pipeline which are sequentially connected;

and for the second instrument pipeline and the third instrument pipeline closest to the second instrument pipeline, a second preset point exists on the fifth pipeline, a connecting line of the second preset point and the fifth bending point is perpendicular to the fifth pipeline, and the second preset point and the first preset point are the same in height.

3. An instrument tube layout method according to claim 2, wherein:

for any two adjacent third instrument pipelines, a third preset point exists in an eighth pipeline of the first bent third instrument pipeline, a connecting line of the third preset point and a fifth bent point of the second bent third instrument pipeline is perpendicular to the eighth pipeline, and the third preset point and the second preset point are the same in height.

4. The instrument tube arrangement method of claim 2, further comprising, when the number of instrument tubes is singular, prior to the step of arranging the first instrument tube:

arranging a central instrument pipeline on a central line of the instrument frame, and bending the central instrument pipeline into a first central pipeline, a second central pipeline and a third central pipeline which are connected in sequence;

the step of arranging the first instrument conduit specifically includes:

a first instrumentation line is disposed on one side of the central instrumentation line.

5. The instrument tube layout method according to claim 1, further comprising, before said step of arranging a first instrument tube, when said number of instrument tubes is a double number:

determining a center line of the instrument rack;

the step of arranging the first instrument conduit includes:

the first instrument tube is arranged on one side of the center line.

6. An instrument tube layout method according to claim 4 or 5, wherein:

arranging and bending two first instrument pipelines, and turning one first instrument pipeline by taking the central line as a reference so as to enable the two first instrument pipelines to be symmetrical.

7. An instrument tube routing method as recited in claim 4, further comprising:

arranging the first pipeline and the first central pipeline at a distance of b, arranging the first pipeline and the fourth pipeline at a distance of b, arranging the fourth pipeline and the seventh pipeline at a distance of b, and arranging a plurality of seventh pipelines at a distance of b;

the third pipeline is arranged at a distance a from the third central pipeline, the third pipeline is arranged at a distance a from the sixth pipeline, the sixth pipeline is arranged at a distance a from the ninth pipeline, and a plurality of ninth pipelines are arranged at a distance a from each other.

8. An instrument tube routing method as recited in claim 7, further comprising:

the aperture of the first instrument pipeline, the second instrument pipeline and the third instrument pipeline is b/2.

9. An instrument tube routing method as recited in claim 4, further comprising:

the bending points of the second central pipeline and the third central pipeline, the second bending point, the fourth bending point and the sixth bending point are the same in height.

10. A thermal control instrument conduit, comprising:

an instrument rack;

the first instrument pipeline is arranged on the instrument frame and provided with a first bending point and a second bending point, and the first bending point and the second bending point jointly divide the first instrument pipeline into a first pipeline, a second pipeline and a third pipeline which are connected in sequence;

the second instrument pipeline is arranged on the instrument frame and provided with a third bending point and a fourth bending point, and the third bending point and the fourth bending point jointly divide the second instrument pipeline into a fourth pipeline, a fifth pipeline and a sixth pipeline which are connected in sequence;

the second pipeline has a first preset point, a connecting line of the first preset point and the third bending point is perpendicular to the second pipeline, and the first preset point and the first bending point have the same height.

Technical Field

The invention relates to the technical field of pipeline design, in particular to an instrument pipeline arrangement sample method and a thermal control instrument pipeline.

Background

The heat control instrument pipeline fan-shaped arrangement is an important component for installing the heat control instrument pipeline and has the function of dispersing the regularly and closely arranged pipelines according to the distance required by instrument installation.

In the current construction process, no specific normative requirement exists, and no construction drawing can be used as a basis. Constructors often roughly measure the blanking size of the pipeline according to the actual installation site on site, or more often carry out blanking according to the past construction experience, so that the construction efficiency is low.

Disclosure of Invention

The invention aims to provide an instrument pipeline arrangement sample method and a thermal control instrument pipeline, which can quickly construct a pilot according to the design specification so as to improve the construction efficiency.

Embodiments of the invention may be implemented as follows:

in a first aspect, the present invention provides an instrument tube arrangement method for arranging a plurality of instrument tubes, comprising: arranging a first instrument pipeline on an instrument frame, bending the first instrument pipeline to enable the first instrument pipeline to form a first bending point and a second bending point, wherein the first bending point and the second bending point jointly divide the first instrument pipeline into a first pipeline, a second pipeline and a third pipeline which are connected in sequence; arranging a second instrument pipeline on the instrument frame, and bending the second instrument pipeline to form a third bending point and a fourth bending point, wherein the third bending point and the fourth bending point jointly divide the second instrument pipeline into a fourth pipeline, a fifth pipeline and a sixth pipeline which are connected in sequence;

the second pipeline has a first preset point, a connecting line of the first preset point and the third bending point is perpendicular to the second pipeline, and the first preset point and the first bending point have the same height.

In an optional embodiment, a plurality of third instrument pipelines are sequentially arranged, and the third instrument pipelines are sequentially bent, so that each third instrument pipeline forms a fifth bending point and a sixth bending point, and the fifth bending point and the sixth bending point jointly divide the third instrument pipeline into a seventh pipeline, an eighth pipeline and a ninth pipeline which are sequentially connected;

and for the second instrument pipeline and the third instrument pipeline closest to the second instrument pipeline, a second preset point exists on the fifth pipeline, a connecting line of the second preset point and the fifth bending point is perpendicular to the fifth pipeline, and the second preset point and the first preset point are the same in height.

In an optional embodiment, for any two adjacent third instrument pipelines, a third preset point exists in an eighth pipeline of the first-bent third instrument pipeline, a connecting line between the third preset point and a fifth bending point of the second-bent third instrument pipeline is perpendicular to the eighth pipeline, and the third preset point and the second preset point are the same in height.

In an alternative embodiment, when the number of the meter lines is singular, before the step of arranging the first meter line, the method further comprises: arranging a central instrument pipeline on a central line of the instrument frame, and bending the central instrument pipeline into a first central pipeline, a second central pipeline and a third central pipeline which are connected in sequence; the step of arranging the first instrument conduit specifically includes: a first instrumentation line is disposed on one side of the central instrumentation line.

In an alternative embodiment, when the number of the meter lines is a double number, before the step of arranging the first meter line, the method further includes: determining a center line of the instrument rack; the step of arranging the first instrument conduit includes: the first instrument tube is arranged on one side of the center line.

In an alternative embodiment, two first instrument pipelines are arranged and bent, and one of the first instrument pipelines is turned over by taking the center line as a reference, so that the two first instrument pipelines are symmetrical.

In an alternative embodiment, the first pipeline is arranged at a distance b from the first central pipeline, the first pipeline is arranged at a distance b from the fourth pipeline, the fourth pipeline is arranged at a distance b from the seventh pipeline, and a plurality of seventh pipelines are arranged at a distance b;

the third pipeline is arranged at a distance a from the third central pipeline, the third pipeline is arranged at a distance a from the sixth pipeline, the sixth pipeline is arranged at a distance a from the ninth pipeline, and a plurality of ninth pipelines are arranged at a distance a from each other.

In an alternative embodiment, the first, second and third instrumentation tubing have a bore diameter of b/2.

In an alternative embodiment, the bending points of the second central tube and the third central tube, the second bending point, the fourth bending point and the sixth bending point are of the same height.

In a second aspect, the present invention provides a thermal control instrument pipeline, comprising: the first instrument pipeline has a first bending point and a second bending point, the first bending point and the second bending point jointly separate the first instrument pipeline into a first pipeline, a second pipeline and a third pipeline which are connected in sequence, the second instrument pipeline has a third bending point and a fourth bending point, and the third bending point and the fourth bending point jointly separate the second instrument pipeline into a fourth pipeline, a fifth pipeline and a sixth pipeline which are connected in sequence;

the second pipeline has a first preset point, a connecting line of the first preset point and the third bending point is perpendicular to the second pipeline, and the first preset point and the first bending point have the same height.

The beneficial effects of the embodiment of the invention include, for example: the embodiment of the invention provides an instrument pipeline arrangement sample method and a thermal control instrument pipeline, which can ensure the attractive construction process, can form a unified and standard instrument frame, increase the bright points of thermal control construction quality, enable constructors to quickly start, and reduce the time cost for measuring bending parameters.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic structural diagram of a thermal control instrument pipeline according to a first embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a thermal control instrument pipeline according to a second embodiment of the present invention;

fig. 3 is a schematic diagram of a meter piping layout method according to a third embodiment of the present invention.

Icon: 1000-thermal control instrument pipeline; 100-a first instrumentation line; 110 — a first conduit; 111-a first bending point; 120-a second conduit; 121-second bending point; 130-a third pipeline; 200-a second instrumentation line; 210-a fourth conduit; 211-third bending point; 220-a fifth pipeline; 221-fourth bending point; 230-sixth conduit; 300-third instrument line; 310-a seventh conduit; 311-fifth bending point; 320-eighth conduit; 321-sixth bending point; 330-ninth conduit; 400-centerline; 410-central instrument line.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present invention, it should be noted that if the terms "upper", "lower", "inside", "outside", etc. indicate an orientation or a positional relationship based on that shown in the drawings or that the product of the present invention is used as it is, this is only for convenience of description and simplification of the description, and it does not indicate or imply that the device or the element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention.

Furthermore, the appearances of the terms "first," "second," and the like, if any, are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

It should be noted that the features of the embodiments of the present invention may be combined with each other without conflict.

The heat control instrument pipeline fan-shaped arrangement is an important component for installing the heat control instrument pipeline and has the function of dispersing the regularly and closely arranged pipelines according to the distance required by instrument installation.

In the current construction process, no specific normative requirement exists, and no construction drawing can be used as a basis. Constructors often roughly measure the blanking size of the pipeline according to the actual installation site on site, or more often carry out blanking according to the past construction experience, so that the construction efficiency is low.

In view of the above problems, embodiments of the present invention provide an instrument pipeline arrangement method and a thermal control instrument pipeline, which can quickly construct a design according to the design specification, so as to improve the construction efficiency.

The first embodiment:

referring to fig. 1, an embodiment of the invention provides a thermal instrumentation pipeline 1000, which includes an instrumentation frame, a first instrumentation pipeline 100 disposed on the instrumentation frame, and a second instrumentation pipeline 200 disposed on the instrumentation frame, wherein the first instrumentation pipeline 100 and the second instrumentation pipeline 200 are disposed on the instrumentation frame adjacent to each other, and the first instrumentation pipeline 100 is closer to a center line 400 of the instrumentation frame than the second instrumentation pipeline 200.

The first instrumentation pipeline 100 has a first bending point 111 and a second bending point 121, and the first bending point 111 and the second bending point 121 together divide the first instrumentation pipeline 100 into a first pipeline 110, a second pipeline 120 and a third pipeline 130 which are connected in sequence. The second instrumentation line 200 has a third bending point 211 and a fourth bending point 221, and the third bending point 211 and the fourth bending point 221 together divide the second instrumentation line 200 into a fourth line 210, a fifth line 220, and a sixth line 230, which are connected in sequence.

In this embodiment, the second pipeline 120 further has a first preset point, and a connection line between the first preset point and the third bending point 211 is perpendicular to the second pipeline 120, and the first preset point and the first bending point 111 have the same height.

In the present embodiment, the meter rack has a center line 400, and in the present embodiment, there are two first meter pipes 100, two first meter pipes 100 are disposed on the meter rack symmetrically to the center line 400, and similarly, there are two second meter pipes 200, and two second meter pipes 200 are disposed on the meter rack symmetrically to the center line 400.

In some embodiments, a plurality of third instrumentation tubing 300 is also disposed on the instrumentation rack, and the plurality of third instrumentation tubing 300 is disposed symmetrically to the centerline 400 of the instrumentation rack. Two of the plurality of third instrumentation lines 300 are disposed on the instrumentation frame adjacent to the two second instrumentation lines 200, respectively, and are further away from the centerline 400 of the instrumentation frame than the second instrumentation lines 200.

In some embodiments, each of the plurality of third instrumentation tubes 300 has a fifth bending point 311 and a sixth bending point 321, and the fifth bending point 311 and the sixth bending point 321 jointly divide the third instrumentation tube 300 into a seventh tube 310, an eighth tube 320 and a ninth tube 330 which are connected in sequence, wherein, for the third instrumentation tube 300 which is closest to the second instrumentation tube 200, a second preset point exists on the fifth tube 220 on the second instrumentation tube 200, a connecting line of the second preset point and the fifth bending point 311 of the third instrumentation tube 300 is perpendicular to the fifth tube 220, and the second preset point and the first preset point have the same height.

And for any adjacent two third instrumentation tubes 300, a third preset point exists for the eighth tube 320 of the third instrumentation tube 300 disposed relatively close to the instrumentation console center line 400, a connecting line of the third preset point and the fifth bending point 311 of the third instrumentation tube 300 disposed relatively far from the instrumentation console center line 400 is perpendicular to the eighth tube 320 of the third instrumentation tube 300 disposed relatively close to the instrumentation console center line 400, and the third preset point and the second preset point are the same in height.

It is understood that the first preset point and the second preset point are the same as the third preset point and the first bending point 111 of the first instrument pipe 100.

In this embodiment, two third instrumentation tubes 300 are disposed on the instrumentation frame, the third instrumentation tubes 300 are disposed on the instrumentation frame adjacent to the second instrumentation tube 200, each of the third instrumentation tubes 300 has a fifth bending point 311 and a sixth bending point 321, the fifth bending point 311 and the sixth bending point 321 together divide the third instrumentation tube 300 into a seventh tube 310, an eighth tube 320 and a ninth tube 330 which are sequentially connected, a second preset point exists on the fifth tube 220 on the second instrumentation tube 200, a connection line between the second preset point and the fifth bending point 311 of the third instrumentation tube 300 is perpendicular to the fifth tube 220, and the second preset point is as high as the first preset point. It is understood that, in other embodiments, the number of the third instrumentation tubes 300 may be different from the actual number of the third tubes 130, and is not limited herein.

Also, in the present embodiment, the first, second, and third instrumentation lines 100, 200, and 300 have a bore diameter of b/2, and in the present embodiment, b/2 is 14 mm. And the first pipe 110 is the same distance from the fourth pipe 210 and the seventh pipe 310 and is a distance b. Of course, in other embodiments, the distance between the first pipe 110 and the fourth pipe 210 and the seventh pipe 310 may not be limited to two times of the aperture of the first instrument pipe 100, the second instrument pipe 200 and the third instrument pipe 300, and may be other distances, as long as the first instrument pipe 100, the second instrument pipe 200 and the third instrument pipe 300 can be smoothly mounted on the instrument rack and the distances therebetween are equal, and the distance is not limited thereto.

In the present embodiment, the heights and distances of the second bending point 121, the fourth bending point 221 and the sixth bending point 321 are the same, and the distance between the second bending point 121, the fourth bending point 221 and the sixth bending point 321 is a, in the present embodiment, a is 200mm, and in the present embodiment, the connection line of the second bending point 121, the fourth bending point 221 and the sixth bending point 321 is a straight line. The second bending point 121, the fourth bending point 221 and the sixth bending point 321 are collinear.

In the present embodiment, the heights from the first bending point 111, the first preset point and the second preset point to the second bending point 121, the fourth bending point 221 and the sixth bending point 321 are h, i.e., the heights are the same, and in the present embodiment, h is 400 mm.

The thermal control instrument pipeline 1000 provided by the embodiment is simple and easy to manufacture, can improve the construction efficiency of constructors while ensuring the attractiveness of the construction process, and can save construction materials and reduce the construction cost.

Second embodiment:

referring to fig. 2, in the thermal control instrument pipeline 1000 provided in this embodiment, a central instrument pipeline 410 is further disposed on a central line 400 of the instrument rack, and the aperture of the central instrument pipeline 410 is the same as that of the first instrument pipeline 100, the second instrument pipeline 200, and the third instrument pipeline 300, the central instrument pipeline 410 has a first central pipeline, a second central pipeline, and a third central pipeline connected in sequence, and the distance from the first central pipeline to the first pipeline 110 is twice the aperture of the central instrument pipeline 410.

In the second embodiment, a central instrument pipeline 410 is disposed on the central line 400, which satisfies that the distances between the seventh pipeline 310 and the first central pipeline of the first pipeline 110 and the fourth pipeline 210 are equal, that is, the distance is b, and the distances between the third pipeline 130, the sixth pipeline 230, the ninth pipeline 330 and the third central pipeline are equal, that is, the distance is a, and the arrangement and bending of the first instrument pipeline 100, the second instrument pipeline 200 and the third instrument pipeline 300 are the same as those in the first embodiment.

According to the thermal control instrument pipeline 1000 provided by the embodiment, the construction efficiency is improved, the construction materials are saved and the construction cost is reduced while the attractiveness of the construction process is ensured.

The third embodiment:

referring to fig. 3, an embodiment of the invention further provides an instrument tube arrangement method.

S1: determining the number of instrument lines

When the quantity of instrument pipeline is the odd number, set up central instrument pipeline 410 on the central line 400 of instrument frame to bend central instrument pipeline 410 and be first central pipeline, second central pipeline and the third central pipeline that connects gradually, and the height distance of the bending point of first central pipeline and second central pipeline apart from the bending point of second central pipeline and third central pipeline is h, arrange first instrument pipeline 100's step and specifically include: one side of the first instrumentation line 100 and the central instrumentation line 410 is disposed. And simultaneously, arranging and bending one first instrument pipeline 100, and turning the first instrument pipeline 100 around the central line 400 as a reference so that the two first instrument pipelines 100 are symmetrical based on the central line 400.

When the number of the meter tubes is a double number, the center line 400 of the meter rack is determined, and arranging the first meter tube 100 includes: the first instrumentation line 100 is disposed to one side of the centerline 400. And simultaneously, arranging and bending one first instrument pipeline 100, and turning the first instrument pipeline 100 around the central line 400 as a reference so that the two first instrument pipelines 100 are symmetrical based on the central line 400.

S2: arranging instrument pipes on instrument rack

First, when the first instrumentation tubing 100 is disposed on the instrumentation frame, the first instrumentation tubing 100 is bent such that the first instrumentation tubing 100 forms a first bending point 111 and a second bending point 121, and such that a height distance between the first bending point 111 and the second bending point 121 is also h, and the first bending point 111 and the second bending point 121 together divide the first instrumentation tubing 100 into a first tubing 110, a second tubing 120, and a third tubing 130 that are sequentially connected. If the number of the instrument pipelines is singular, the distance between the first pipeline 110 and the first central pipeline is b, and the distance between the third pipeline 130 and the third central pipeline is a.

Further, a second instrument pipeline 200 is arranged on the instrument frame, and the second instrument pipeline 200 is bent, so that the second instrument pipeline 200 forms a third bending point 211 and a fourth bending point 221, the third bending point 211 and the fourth bending point 221 jointly divide the second instrument pipeline 200 into a fourth pipeline 210, a fifth pipeline 220 and a sixth pipeline 230 which are sequentially connected, wherein the second pipeline 120 has a first preset point, a connecting line of the first preset point and the third bending point 211 is perpendicular to the second pipeline 120, and the first preset point and the first bending point 111 have the same height.

In detail, when the second instrumentation pipeline 200 is arranged, the distance from the fourth pipeline 210 to the first pipeline 110 is b, the height distance from a point on the second pipeline 120 to the second bending point 121 is h, a connection line perpendicular to the second pipeline 120 is made through the point and intersects with the second instrumentation pipeline 200, the intersection point is the third bending point 211 of the second instrumentation pipeline 200, and at this time, the fourth bending point 221 of the second instrumentation pipeline 200 is made at the same time to ensure that the fourth bending point 221 and the second bending point 121 are at the same height and the distance from the fourth bending point 221 to the second bending point 121 is a.

And simultaneously, arranging and bending a second instrument pipeline 200, and turning the second instrument pipeline 200 around the central line 400 as a reference so that the two second instrument pipelines 200 are symmetrical based on the central line 400.

Further, a plurality of third instrumentation tubes 300 are sequentially arranged on the instrumentation frame, and the bending process is sequentially performed on the plurality of third instrumentation tubes 300, so that each third instrumentation tube 300 forms a fifth bending point 311 and a sixth bending point 321, and the fifth bending point 311 and the sixth bending point 321 jointly divide the third instrumentation tube 300 into a seventh tube 310, an eighth tube 320, and a ninth tube 330 which are sequentially connected.

For the second instrumentation pipeline 200 and the third instrumentation pipeline 300 closest to the second instrumentation pipeline 200, a second preset point exists on the fifth pipeline 220, a connecting line of the second preset point and the fifth bending point 311 is perpendicular to the fifth pipeline 220, and the second preset point and the first preset point are the same in height. In detail, when the third instrumentation pipeline 300 is arranged, the distance from the seventh pipeline 310 to the fourth pipeline 210 is b, the height distance from a point on the fifth pipeline 220 to the fourth bending point 221 is h, a connection line perpendicular to the fifth pipeline 220 is made through the point and intersects with the third instrumentation pipeline 300, the intersection point is the fifth bending point 311 of the third instrumentation pipeline 300, and at this time, the sixth bending point 321 of the third instrumentation pipeline 300 is made at the same time to ensure that the sixth bending point 321 and the fourth bending point 221 are at the same height and the distance between the sixth bending point 321 and the first bending point is a.

And simultaneously, a third instrumentation line 300 is laid and bent, and the third instrumentation line 300 is turned over with reference to the center line 400, so that the two third instrumentation lines 300 are symmetrical with respect to the center line 400.

Further, for any two adjacent third instrument pipelines 300, a third preset point exists in the eighth pipeline 320 of the first-bent third instrument pipeline 300, a connecting line between the third preset point and the fifth bending point 311 of the second-bent third instrument pipeline 300 is perpendicular to the eighth pipeline 320, and the third preset point and the second preset point are the same in height.

In detail, when the third instrument tube 300 distant from the second instrument tube 200 is disposed, the third instrument tube 300 not close to the second instrument tube 200 is the third instrument tube 300 distant from the second instrument tube 200. The distance between two adjacent seventh pipelines 310 is b, the height distance from a point to the sixth bending point 321 on the eighth pipeline 320 of the previous third instrument pipeline 300 is h, a connection line perpendicular to the eighth pipeline 320 is made through the point and intersects with the third instrument pipeline 300 to be bent, the intersection point is the fifth bending point 311 of the third instrument pipeline 300 to be bent, and at the moment, the sixth bending point 321 of the third instrument pipeline 300 to be bent is made at the same time to ensure that the sixth bending point 321 and the sixth bending point 321 of the previous third instrument pipeline 300 are at the same height and the distance between the sixth bending points 321 of the two third instrument pipelines 300 is a.

And simultaneously, a third instrumentation line 300 is laid and bent, and the third instrumentation line 300 is turned over with reference to the center line 400, so that the two third instrumentation lines 300 are symmetrical with respect to the center line 400.

It will be appreciated that a corresponding number of third instrumentation lines 300 may be designed according to actual needs, in this embodiment two third instrumentation lines 300 are arranged and bent and the two third instrumentation lines 300 are provided for this based on the center line 400.

S3: fixing instrument pipes on instrument rack

The instrument pipeline arrangement sample method provided by the embodiment ensures that the construction process is attractive, the fan-shaped instrument frame with unified specification is formed, the bright spots of thermal control construction quality are increased, constructors can quickly get on the hand, the construction efficiency is improved, construction materials are saved, the construction cost is reduced, and the time cost for measuring bending parameters can be reduced.

In summary, the embodiments of the present invention provide an instrument pipeline arrangement method and a thermal control instrument pipeline 1000, which can ensure an attractive construction process, form a unified and standardized instrument rack, increase bright spots of thermal control construction quality, enable a constructor to quickly start up, and reduce the time cost for measuring bending parameters, and the thermal control instrument pipeline 1000 is easy to manufacture, can improve the construction efficiency of the constructor while ensuring the attractive construction process, and can save construction materials and reduce construction cost.

The above description is only for the specific embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.