阅读说明：本技术 建筑布线落地检测方法 (Building wiring landing detection method ) 是由 不公告发明人 于 2021-09-06 设计创作，主要内容包括：本发明涉及一种建筑布线落地检测方法,其特征在于包括如下步骤,步骤a、设计一款布线落地检测系统,该布线落地检测系统包括架设在地面(8)上的横移架(1),所述横移架(1)沿着水管(2)的走向设于水管(2)上方；步骤b、检测时,电动缸(12)向下伸出使第一夹爪(14)和第二夹爪(15)夹持在水管(2)上,然后在电机(18)驱动下,基座(11)横移以使第一夹爪(14)和第二夹爪(15)沿着水管(2)横移；如果铺设水管(2)时没有严格遵循横平竖直,那么在第一夹爪第一夹爪(14)和第二夹爪(15)横移过程中,第一活动支架(3)绕转轴(5)转动,滚轮(7)绕转轴(5)并且沿着刻度标识(10)产生周向位移；步骤c、检测人员可以通过在刻度标识(10)上读数来确定水管(2)的铺设是否达标,若超过设计值即判定为不合格。(The invention relates to a building wiring floor detection method which is characterized by comprising the following steps of a, designing a wiring floor detection system, wherein the wiring floor detection system comprises a transverse moving frame (1) erected on the ground (8), and the transverse moving frame (1) is arranged above a water pipe (2) along the trend of the water pipe (2); step b, during detection, the electric cylinder (12) extends downwards to enable the first clamping jaw (14) and the second clamping jaw (15) to be clamped on the water pipe (2), and then the base (11) moves transversely to enable the first clamping jaw (14) and the second clamping jaw (15) to move transversely along the water pipe (2) under the driving of the motor (18); if the water pipe (2) is laid without strictly following the horizontal and vertical directions, the first movable bracket (3) rotates around the rotating shaft (5) during the horizontal moving of the first clamping jaw (14) and the second clamping jaw (15), and the roller (7) generates circumferential displacement around the rotating shaft (5) and along the scale mark (10); and c, determining whether the laying of the water pipe (2) reaches the standard or not by reading on the scale mark (10) by a detector, and judging that the water pipe is unqualified if the laying of the water pipe exceeds a designed value.)

1. A floor detection method for building wiring is characterized by comprising the following steps,

step a, designing a wiring floor detection system, wherein the wiring floor detection system comprises a transverse moving frame (1) erected on the ground (8), and the transverse moving frame (1) is arranged above a water pipe (2) along the trend of the water pipe (2);

one end of the transverse moving frame (1) is provided with a first movable support (3), the bottom of the first movable support (3) is provided with a fixed seat (4), the fixed seat (4) is positioned at the turning position of the water pipe (2), the fixed seat (4) is fixed relative to the water pipe (2), and the first movable support (3) is connected with the fixed seat (4) through a rotating shaft (5); a second movable support (6) is arranged at the other end of the transverse moving frame (1), rollers (7) are arranged at the bottom of the second movable support (6), the rollers (7) move on an identification plate (9) laid on the ground (8), and the identification plate (9) is fixed relative to the water pipe (2); the marking plate (9) is provided with a scale mark (10) along the moving track of the roller (7), the transverse moving frame (1) is further provided with a base (11) capable of transversely moving, the base (11) is provided with an electric cylinder (12) extending downwards, the movable end of the electric cylinder (12) is provided with a clamping jaw sliding block (13), and one side of the clamping jaw sliding block (13) is fixed with a first clamping jaw (14); a movable second clamping jaw (15) is arranged on the other side of the clamping jaw sliding block (13), springs (16) for clamping the clamping jaws are arranged between the first clamping jaw (14) and the second clamping jaw (15), semicircular clamping grooves (17) are formed in the first clamping jaw (14) and the second clamping jaw (15), and a motor (18) for driving the base (11) to move transversely is further arranged at one end of the transverse moving frame (1); the fixed seat (4) is fixed at a corner of the water pipe (2), the electric cylinder (12) extends downwards to enable the first clamping jaw (14) and the second clamping jaw (15) to clamp the water pipe (2), and the motor (18) drives the base (11) to transversely move so that the first clamping jaw (14) and the second clamping jaw (15) transversely move along the water pipe (2); the bottom of the fixed seat (4) is provided with an elastic hoop (19) which is opened in one direction, the elastic hoop (19) is clamped on the water pipe (2) connected to one side of a corner, one end of the first movable support (3) is provided with a movable seat (20), and the movable seat (20) is attached to the fixed seat (4) and is connected with the fixed seat through the rotating shaft (5); the other end of the first movable bracket (3) is provided with a first connecting plate (21), and the first connecting plate (21) is connected to one end of the transverse moving frame (1); the marking plate (9) is provided with a circular arc-shaped sliding groove (22) taking the rotating shaft (5) as an axis, the scale mark (10) is arranged along the sliding groove (22), the surface of the roller (7) is provided with an annular guide bulge (23), and the guide bulge (23) is embedded into the sliding groove (22);

step b, during detection, the electric cylinder (12) extends downwards to enable the first clamping jaw (14) and the second clamping jaw (15) to be clamped on the water pipe (2), and then the base (11) moves transversely to enable the first clamping jaw (14) and the second clamping jaw (15) to move transversely along the water pipe (2) under the driving of the motor (18); if the water pipe (2) is laid without strictly following the horizontal and vertical directions, the first movable bracket (3) rotates around the rotating shaft (5) during the horizontal moving of the first clamping jaw (14) and the second clamping jaw (15), and the roller (7) generates circumferential displacement around the rotating shaft (5) and along the scale mark (10);

and c, determining whether the laying of the water pipe (2) reaches the standard or not by reading on the scale mark (10) by a detector, and judging that the water pipe is unqualified if the laying of the water pipe exceeds a designed value.

2. The building wiring floor detection method according to claim 1, wherein a side of the first clamping jaw (14) facing the second clamping jaw (15) is provided with a first mounting piece (28), a side of the second clamping jaw (15) facing the first clamping jaw (14) is provided with a second mounting piece (29), the first mounting piece (28) is opposite to the second mounting piece (29), the spring (16) is connected to the first mounting piece (28) and the second mounting piece (29), and the first clamping jaw (14) and the second clamping jaw (15) are both wide at the top and narrow at the bottom.

Technical Field

The invention relates to the field of building detection, in particular to a floor detection method for building wiring.

Background

The water and electricity wiring of indoor buildings needs to be grounded, firstly, a wire slot is formed in the ground, and then, a water pipe wire is embedded underground. If the construction is completed, it is difficult to confirm the pre-buried position. Therefore, when the water and electricity are embedded, the water and electricity should be laid strictly according to the principle of horizontal and vertical. Taking laying water pipes as an example, the lines need to be horizontal and vertical, and the distance between cold water pipes and hot water pipes is not less than 15 cm. If the principle of horizontal and vertical is not strictly followed when the water pipe is laid, the water pipe is easy to explode when the hole is drilled in the later period.

Disclosure of Invention

In view of the above, the present invention provides a method for detecting a floor of a building wiring, so as to solve the above problems.

In order to solve the technical problems, the technical scheme of the invention is as follows:

a floor detection method for building wiring is characterized by comprising the following steps,

step a, designing a wiring floor detection system, wherein the wiring floor detection system comprises a transverse moving frame (1) erected on the ground (8), and the transverse moving frame (1) is arranged above a water pipe (2) along the trend of the water pipe (2);

one end of the transverse moving frame (1) is provided with a first movable support (3), the bottom of the first movable support (3) is provided with a fixed seat (4), the fixed seat (4) is positioned at the turning position of the water pipe (2), the fixed seat (4) is fixed relative to the water pipe (2), and the first movable support (3) is connected with the fixed seat (4) through a rotating shaft (5); a second movable support (6) is arranged at the other end of the transverse moving frame (1), rollers (7) are arranged at the bottom of the second movable support (6), the rollers (7) move on an identification plate (9) laid on the ground (8), and the identification plate (9) is fixed relative to the water pipe (2); the marking plate (9) is provided with a scale mark (10) along the moving track of the roller (7), the transverse moving frame (1) is further provided with a base (11) capable of transversely moving, the base (11) is provided with an electric cylinder (12) extending downwards, the movable end of the electric cylinder (12) is provided with a clamping jaw sliding block (13), and one side of the clamping jaw sliding block (13) is fixed with a first clamping jaw (14); a movable second clamping jaw (15) is arranged on the other side of the clamping jaw sliding block (13), springs (16) for clamping the clamping jaws are arranged between the first clamping jaw (14) and the second clamping jaw (15), semicircular clamping grooves (17) are formed in the first clamping jaw (14) and the second clamping jaw (15), and a motor (18) for driving the base (11) to move transversely is further arranged at one end of the transverse moving frame (1); the fixed seat (4) is fixed at a corner of the water pipe (2), the electric cylinder (12) extends downwards to enable the first clamping jaw (14) and the second clamping jaw (15) to clamp the water pipe (2), and the motor (18) drives the base (11) to transversely move so that the first clamping jaw (14) and the second clamping jaw (15) transversely move along the water pipe (2); the bottom of the fixed seat (4) is provided with an elastic hoop (19) which is opened in one direction, the elastic hoop (19) is clamped on the water pipe (2) connected to one side of a corner, one end of the first movable support (3) is provided with a movable seat (20), and the movable seat (20) is attached to the fixed seat (4) and is connected with the fixed seat through the rotating shaft (5); the other end of the first movable bracket (3) is provided with a first connecting plate (21), and the first connecting plate (21) is connected to one end of the transverse moving frame (1); the marking plate (9) is provided with a circular arc-shaped sliding groove (22) taking the rotating shaft (5) as an axis, the scale mark (10) is arranged along the sliding groove (22), the surface of the roller (7) is provided with an annular guide bulge (23), and the guide bulge (23) is embedded into the sliding groove (22);

step b, during detection, the electric cylinder (12) extends downwards to enable the first clamping jaw (14) and the second clamping jaw (15) to be clamped on the water pipe (2), and then the base (11) moves transversely to enable the first clamping jaw (14) and the second clamping jaw (15) to move transversely along the water pipe (2) under the driving of the motor (18); if the water pipe (2) is laid without strictly following the horizontal and vertical directions, the first movable bracket (3) rotates around the rotating shaft (5) during the horizontal moving of the first clamping jaw (14) and the second clamping jaw (15), and the roller (7) generates circumferential displacement around the rotating shaft (5) and along the scale mark (10);

and c, determining whether the laying of the water pipe (2) reaches the standard or not by reading on the scale mark (10) by a detector, and judging that the water pipe is unqualified if the laying of the water pipe exceeds a designed value.

In the scheme, a first mounting piece (28) is arranged on one side, facing the second clamping jaw (15), of the first clamping jaw (14), a second mounting piece (29) is arranged on one side, facing the first clamping jaw (14), of the second clamping jaw (15), the first mounting piece (28) is opposite to the second mounting piece (29), the spring (16) is connected to the first mounting piece (28) and the second mounting piece (29), and the first clamping jaw (14) and the second clamping jaw (15) are both wide at the top and narrow at the bottom.

The technical effects of the invention are mainly reflected in the following aspects:

the building wiring landing detection method is installed at the corner of the water pipe to determine whether the arrangement of the water pipe is horizontal and vertical. Specifically, the water pipes on two sides of the corner are substantially vertical, and the water pipe on one side is used as a fixed carrier, namely, the fixed seat is fixed at the corner of the water pipe. The first movable support on the fixed seat is connected with the fixed seat through a rotating shaft. When detecting, electronic jar stretches out downwards and makes first clamping jaw and second clamping jaw centre gripping on the water pipe, then under motor drive, the base sideslip is so that first clamping jaw and second clamping jaw sideslip along the water pipe. If the water pipe is laid without strictly following the horizontal and vertical direction, the first movable bracket rotates around the rotating shaft during the horizontal movement of the first clamping jaw and the second clamping jaw, and the roller generates circumferential displacement around the rotating shaft and along the scale marks. Whether the laying of the water pipe reaches the standard can be determined by reading on the scale marks.

Drawings

FIG. 1: a first overall view of the wiring landing detection system adopted by the invention;

FIG. 2: a second overall view of the wiring landing detection system employed by the present invention;

FIG. 3: a first partial view of a wiring landing detection system employed by the present invention; (ii) a

FIG. 4: a second partial view of the wiring landing detection system employed by the present invention; (ii) a

FIG. 5: a third partial view of a wiring floor detection system employed by the present invention.

Detailed Description

The following detailed description of the embodiments of the present invention is provided in order to make the technical solution of the present invention easier to understand and understand.

A floor detection method for building wiring is characterized by comprising the following steps,

step a, designing a wiring floor detection system.

In one embodiment, as shown in fig. 1-3.

The floor detection system for building wiring provided by the embodiment comprises a transverse moving frame 1 erected on the ground 8, wherein the transverse moving frame 1 is arranged above a water pipe 2 along the trend of the water pipe 2, one end of the transverse moving frame 1 is provided with a first movable support 3, the bottom of the first movable support 3 is provided with a fixed seat 4, the fixed seat 4 is positioned at the turning part of the water pipe 2, the fixed seat 4 is fixed relative to the water pipe 2, the first movable support 3 and the fixed seat 4 are connected through a rotating shaft 5, the other end of the transverse moving frame 1 is provided with a second movable support 6, the bottom of the second movable support 6 is provided with a roller 7, the roller 7 moves on a marking plate 9 laid on the ground 8, the marking plate 9 is fixed relative to the water pipe 2, the marking plate 9 is provided with a scale mark 10 along the moving track of the roller 7, the transverse moving frame 1 is also provided with a base 11 capable of transversely moving, the base 11 is provided with an electric cylinder 12 extending downwards, a clamping jaw sliding block 13 is arranged at the movable end of the electric cylinder 12, a first clamping jaw 14 is fixed at one side of the clamping jaw sliding block 13, a movable second clamping jaw 15 is arranged at the other side of the clamping jaw sliding block 13, a spring 16 for clamping the first clamping jaw 14 and the second clamping jaw 15 is arranged between the first clamping jaw 14 and the second clamping jaw 15, semicircular clamping grooves 17 are formed in the first clamping jaw 14 and the second clamping jaw 15, and a motor 18 for driving the base 11 to move transversely is further arranged at one end of the transverse moving frame 1; the fixing seat 4 is fixed at a corner of the water pipe 2, the electric cylinder 12 extends downwards to enable the first clamping jaw 14 and the second clamping jaw 15 to clamp the water pipe 2, and the motor 18 drives the base 11 to move transversely to enable the first clamping jaw 14 and the second clamping jaw 15 to move transversely along the water pipe 2; when the water pipes 2 connected at the corner are not vertical, the first movable bracket 3 rotates around the rotating shaft 5 during the transverse movement of the first clamping jaw 14 and the second clamping jaw 15, and the roller 7 generates circumferential displacement around the rotating shaft 5 and along the scale mark 10.

In one embodiment, as shown in FIG. 4.

According to the floor detection method for building wiring provided by the embodiment, the bottom of the fixed seat 4 is provided with the elastic hoop 19 which is opened in one direction, the elastic hoop 19 is clamped on the water pipe 2 connected to one side of a turning part, one end part of the first movable support 3 is provided with the movable seat 20, and the movable seat 20 is attached to the fixed seat 4 and is connected with the fixed seat through the rotating shaft 5.

In this embodiment, the fixing seat 4 needs to use the water pipe 2 on one side as a fixing carrier, that is, the fixing seat 4 is fixed at the corner of the water pipe 2. When the fixed seat 4 is fixed at the corner of the water pipe 2, the rotating shaft 5 is positioned right above the corner. For example, one side of the water pipe 2 at two sides of the corner is used as a longitudinal water pipe 2, and the other side is used as a transverse water pipe 2. By clamping the elastic clamp 19 on the longitudinal water pipe 2, the cross sliding frame 1 can be arranged right above the transverse water pipe 2 along the trend of the transverse water pipe 2. Therefore, the spring clip 19 is not provided directly below the rotary shaft 5, but is provided in a slightly outward position.

In one embodiment, as shown in FIG. 2.

In the floor detection method for the building wiring provided by the embodiment, the other end part of the first movable bracket 3 is provided with the first connecting plate 21, and the first connecting plate 21 is connected to one end of the transverse moving frame 1. The top of the second movable support 6 is provided with a second connecting plate 24, and the second connecting plate 24 is connected with the other end of the transverse moving frame 1.

In the present embodiment, the traverse frame 1 is fixed by the first link plate 21 provided on the first movable bracket 3 and the second link plate 24 provided on the second movable bracket 6. The location of the specific connection is near, but not completely at, both ends of the traversing frame 1. As the space left by the ends houses the motor 18 and associated drive components.

In one embodiment, as shown in FIG. 5.

In the method for detecting the floor of the building wiring provided by the embodiment, the identification plate 9 is provided with the arc-shaped sliding groove 22 taking the rotating shaft 5 as the axis, the scale mark 10 is arranged along the sliding groove 22, the surface of the roller 7 is provided with the annular guide bulge 23, and the guide bulge 23 is embedded into the sliding groove 22.

In the embodiment, the circular arc-shaped sliding groove 22 is arranged on the identification plate 9, so that the identification plate 9 and the roller 7 are in track connection, friction can be reduced, sliding is easier, and the movable track can be determined due to the arranged track. Furthermore, the graduation marks 10 are arranged along the sliding groove 22, and the data thereof can be immediately displayed when the roller 7 moves relative to the marking plate 9. This also makes it possible to quickly determine whether the laying of the water pipes 2 meets the standards of horizontal and vertical.

In one embodiment, as shown in FIG. 1.

In the floor detection method for building wiring provided by the embodiment, the transverse moving frame 1 is further provided with a slide rail 25, the slide rail 25 is provided with a slide block 26, the base 11 is arranged on the slide block 26, the transverse moving frame 1 is further provided with a belt 27 positioned above the slide rail 25, the base 11 is connected to the belt 27, and the motor 18 is in transmission connection with the belt 27.

In this embodiment, a drive device is actually provided. The motor 18 arranged at the end of the transverse moving frame 1 drives the belt 27 to transmit, so that the sliding block 26 can transversely move along the sliding rail 25. This traversing process occurs after the first jaw 14 and the second jaw 15 are clamped on the water pipe 2, and the second movable bracket 6 can be moved during the driving of the first jaw 14 and the second jaw 15 to traverse, depending on whether the water pipe 2 is arranged horizontally or vertically.

In one embodiment, as shown in FIG. 3.

In the floor detection method for building wiring provided by the embodiment, the first mounting piece 28 is arranged on one side of the first clamping jaw 14 facing the second clamping jaw 15, the second mounting piece 29 is arranged on one side of the second clamping jaw 15 facing the first clamping jaw 14, the first mounting piece 28 is opposite to the second mounting piece 29, the spring 16 is connected to the first mounting piece 28 and the second mounting piece 29, and the first clamping jaw 14 and the second clamping jaw 15 are both wide in top and narrow in bottom.

In this embodiment, the first jaw 14 and the second jaw 15 having a wide upper portion and a narrow lower portion are provided to further facilitate the clamping of the first jaw 14 and the second jaw 15 on the water pipe 2.

Step b, during detection, the electric cylinder 12 extends downwards to enable the first clamping jaw 14 and the second clamping jaw 15 to be clamped on the water pipe 2, and then the base 11 moves transversely to enable the first clamping jaw 14 and the second clamping jaw 15 to move transversely along the water pipe 2 under the driving of the motor 18; if the water pipe 2 is laid without strictly following the horizontal and vertical direction, during the horizontal movement of the first clamping jaw 14 and the second clamping jaw 15, the first movable bracket 3 rotates around the rotating shaft 5, and the roller 7 generates circumferential displacement around the rotating shaft 5 and along the scale mark 10;

and c, determining whether the laying of the water pipe 2 reaches the standard or not by reading on the scale mark 10 by a detector, and judging that the laying of the water pipe is unqualified if the laying of the water pipe exceeds the designed value.

The above are only typical examples of the present invention, and besides, the present invention may have other embodiments, and all the technical solutions formed by equivalent substitutions or equivalent changes are within the scope of the present invention as claimed.