CN117516476A - Verticality detector for quality detector of building energy-saving engineering - Google Patents
Verticality detector for quality detector of building energy-saving engineering Download PDFInfo
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- CN117516476A CN117516476A CN202311570302.8A CN202311570302A CN117516476A CN 117516476 A CN117516476 A CN 117516476A CN 202311570302 A CN202311570302 A CN 202311570302A CN 117516476 A CN117516476 A CN 117516476A
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- 238000001514 detection method Methods 0.000 claims abstract description 46
- 230000007246 mechanism Effects 0.000 claims abstract description 13
- 230000002457 bidirectional effect Effects 0.000 claims description 15
- 230000009467 reduction Effects 0.000 claims description 13
- 230000005540 biological transmission Effects 0.000 claims description 11
- 238000010276 construction Methods 0.000 claims description 9
- 238000003466 welding Methods 0.000 claims description 3
- 239000000463 material Substances 0.000 claims description 2
- 229910001220 stainless steel Inorganic materials 0.000 claims description 2
- 239000010935 stainless steel Substances 0.000 claims description 2
- 210000002445 nipple Anatomy 0.000 claims 5
- 230000001360 synchronised effect Effects 0.000 abstract description 8
- 210000001503 joint Anatomy 0.000 description 10
- 238000010586 diagram Methods 0.000 description 5
- 230000009471 action Effects 0.000 description 3
- 230000007547 defect Effects 0.000 description 2
- 238000007689 inspection Methods 0.000 description 2
- 238000009435 building construction Methods 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 238000001125 extrusion Methods 0.000 description 1
- 238000000034 method Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 230000008569 process Effects 0.000 description 1
- 230000001915 proofreading effect Effects 0.000 description 1
- 238000000926 separation method Methods 0.000 description 1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C9/00—Measuring inclination, e.g. by clinometers, by levels
- G01C9/02—Details
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C9/00—Measuring inclination, e.g. by clinometers, by levels
- G01C9/02—Details
- G01C9/06—Electric or photoelectric indication or reading means
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C9/00—Measuring inclination, e.g. by clinometers, by levels
- G01C9/02—Details
- G01C9/06—Electric or photoelectric indication or reading means
- G01C2009/066—Electric or photoelectric indication or reading means optical
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Abstract
The invention discloses a detector for the perpendicularity of a quality detector of a building energy-saving engineering, and particularly relates to the technical field of building detection tools, which mainly comprises a semicircular supporting strip, wherein a connecting supporting strip is arranged on one side of the semicircular supporting strip, two sliding concave columns are connected inside the connecting supporting strip and the semicircular supporting strip in a sliding manner, and a linkage detection mechanism is arranged inside the sliding concave columns; the linkage detection mechanism comprises an inclined hinging rod arranged inside the sliding concave column, a supporting shaft is installed on the inner wall of the inclined hinging rod and close to the top end of the inclined hinging rod, and a concave sleeving block is fixedly connected to one end of the supporting shaft. According to the invention, the four perpendicularity sensors can be respectively positioned at the four surface positions of the building energy-saving engineering supporting column through the linkage detection mechanism, the distance sensor senses the distance to the building energy-saving engineering supporting column, and the four perpendicularity sensors are accurately butted to the four detection surfaces of the building energy-saving engineering supporting column in a synchronous manner, so that synchronous automatic detection is realized, and the detection efficiency is improved.
Description
Technical Field
The invention relates to the technical field of building detection tools, in particular to a verticality detector of a building energy-saving engineering quality detector.
Background
The utility model provides a building energy-saving engineering quality detector straightness detector that hangs down is an instrument that is used for detecting building straightness, and it can help architects and engineers to guarantee the vertical precision of building in the design and construction process to guarantee the quality of building under construction.
Among the technical documents disclosed, patent publication No. CN213812270U discloses a perpendicularity detector for building supervision, which aims at solving a series of problems that deviation of perpendicularity cannot be found in advance in building construction in the prior art, and only a flat building can be measured, and data errors measured on a rough building surface are overlarge; according to the patent, the supporting plate is arranged, so that the verticality of a rough building can be measured rapidly and accurately, and a flat building can be measured by rotating a screw; by arranging the pointer adjusting screw, the accuracy of measuring verticality can be improved, so that a plurality of problems caused by not finding verticality deviation in time in the building engineering are improved; however, the perpendicularity detector has the following defects:
when the perpendicularity detector detects the quality of the building energy-saving engineering, a wall body supporting column is detected, the wall body supporting column is provided with a plurality of surfaces to be detected, one surface is detected and then needs to be moved to the other surface again for detection, the detection of one wall body supporting column takes a long time, the detection efficiency is low, and therefore the perpendicularity detector which does not need repeated movement detection is needed.
Disclosure of Invention
In order to overcome the defects in the prior art, the invention provides a verticality detector for a quality detector of a building energy-saving engineering.
In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a building energy-saving engineering quality detector straightness detector that hangs down, includes semicircle branch, one side of semicircle branch is equipped with the connection branch, the inside of connection branch and semicircle branch all sliding connection have two slip concave posts, the inside of slip concave post is equipped with linkage detection mechanism;
the linkage detection mechanism comprises an inclined hinging rod arranged inside a sliding concave column, a supporting shaft is arranged on the inner wall of the inclined hinging rod and close to the top end of the inclined hinging rod, a concave sleeving block is fixedly connected to one end of the supporting shaft, a linkage screw is connected to the inner thread of the concave sleeving block, a guiding support frame is connected to the outer wall of the concave sleeving block in a sliding mode, a speed reduction driving motor is connected to the top end of the linkage screw in a coaxial transmission mode, a linkage sleeving plate is fixedly connected to one end of the sliding concave column, and a perpendicularity sensor is fixedly connected to one end of the linkage sleeving plate.
Preferably, the sliding concave columns and the supporting shafts are rotationally connected with the inclined hinging rods, the sliding concave columns and the inclined hinging rods are made of stainless steel materials, the speed reduction driving motor and the semicircular supporting strips are fixedly connected with the guiding supporting frames, and the semicircular supporting strips and the connecting supporting strips are symmetrically arranged.
Preferably, the outer wall fixedly connected with of straightness sensor cup joints the linkage piece, one side of straightness sensor is equipped with and cup joints the linkage piece fixed connection's distance sensor, the top welding of cup joints the linkage piece has the screw thread to cup joint a piece the screw thread cup joints the inside threaded connection of a piece and has the guide drive screw, the coaxial transmission in top of guide drive screw is connected with servo drive motor, the screw thread cup joints sliding connection between a piece and the linkage cup joint the board, fixed connection between servo drive motor and the linkage cup joint the board.
According to the technical scheme, four deceleration driving motors are started, the linkage screw rod drives the concave sleeving block to move upwards along the inside of the guide supporting frame under the action of threads, the supporting shaft drives the inclined hinging rod to move upwards, the inclined hinging rod drives the sliding concave column to move from the inside of the semicircular supporting bar, the other two sliding concave columns can move from the inside of the connecting supporting bar, the sliding concave column drives the linkage sleeving plate to move, the perpendicularity sensor drives the sleeving linkage block to move, the distance sensor senses the distance of the building energy-saving engineering supporting column, when the sensed distance of the distance sensor reaches the set distance of the controller, the sleeving linkage block drives the perpendicularity sensor to contact with the detection surface of the building energy-saving engineering supporting column, the end part of the perpendicularity sensor generates extrusion shrinkage, the four servo driving motors are started, the servo driving motor drives the guide driving screw rod to rotate in the inside of the linkage sleeving plate, the guide driving screw rod drives the threaded sleeving supporting block to move upwards in the inside of the linkage sleeving plate, and simultaneously the thread sleeving supporting block drives the sleeving block to move upwards along the detection surface of the building energy-saving engineering supporting column.
Preferably, the top of semicircle branch strip just is located fixedly connected with and adjusts the framed board between two direction framed, the inside of adjusting the framed board is equipped with locating component, locating component is including setting up the adjusting screw who adjusts the framed board inside, adjusting screw's outer wall threaded connection has the screw thread to overlap the board, the top welding of screw thread cover board has the linkage V-arrangement board the inner wall fixedly connected with turning locating plate of linkage V-arrangement board, the top fixedly connected with of turning locating plate cup joints the fixed block, just cup joints the inside fixedly connected with laser proofreading ware of fixed block, sliding connection between screw thread cover board and the adjusting framed board, the cross section shape of turning locating plate is established to L shape.
According to the technical scheme, after the laser calibrator is electrified, a red laser spot is generated to irradiate the corner position on the building energy-saving engineering support column, the adjusting screw is rotated in the adjusting frame plate, the threaded sleeve connecting plate drives the linkage V-shaped plate to enable the corner positioning plate to move, and the corner positioning plate can be in contact with the corner line position of the building energy-saving engineering support column.
Preferably, two linkage struts are installed to connection branch and semicircle branch junction top, two the linkage struts respectively with semicircle branch and connection branch one-to-one fixed connection, the top of linkage strut is connected with adjusting part, adjusting part includes the linkage extension board of fixed connection on linkage strut top, one side of linkage strut is equipped with the first screw thread bridging piece with linkage extension board fixed connection, one side of first screw thread bridging piece is equipped with the second screw thread bridging piece, the inside threaded connection of second screw thread bridging piece has two-way screw rods, the outer wall sliding connection of first screw thread bridging piece has the guide frame board, the coaxial transmission of one end of two-way screw rods is connected with the speed reduction linkage motor, one side fixedly connected with two handles of guide frame, two be equipped with the controller between the handle, threaded connection between second screw thread bridging piece and the two opposite and symmetry settings of outer wall two screw threads of two-way screw rods, fixed connection between speed reduction motor and controller and the guide frame, sliding connection between second screw thread bridging piece and the guide frame board.
According to the technical scheme, the pressing controller starts the forward driving of the speed-reducing linkage motor, the speed-reducing linkage motor drives the bidirectional screw rod to rotate in the guide frame plate, the guide frame plate moves forward in the bidirectional screw rod, the second threaded sleeve joint block moves backward in the guide frame plate, the linkage support column drives the semicircular support column to move forward, the other linkage support column drives the connecting support column to move backward, the semicircular support column and the connecting support column are separated from the building energy-saving engineering support column, the semicircular support column and the connecting support column are located on two sides of the next building energy-saving engineering support column, the speed-reducing linkage motor is started to drive the bidirectional screw rod to rotate in the guide frame plate, and the semicircular support column and the connecting support column can be close to each other to detect the next building energy-saving engineering support column.
The invention has the technical effects and advantages that:
according to the invention, the four perpendicularity sensors can be respectively positioned at the four surface positions of the building energy-saving engineering supporting column through the linkage detection mechanism, the four deceleration driving motors are started, the inclined hinging rod drives the sliding concave column to move from the inside of the semicircular supporting strip, the distance sensor senses the distance to the building energy-saving engineering supporting column, the sleeved linkage block drives the perpendicularity sensors to contact the detection surface of the building energy-saving engineering supporting column, the four perpendicularity sensors can be synchronously and accurately butted to the four detection surfaces of the building energy-saving engineering supporting column, synchronous automatic detection is realized, individual surface detection is not needed, the detection time is greatly shortened, and the detection efficiency is improved;
according to the invention, the positioning assembly is adopted to open the laser proofer in the sleeving fixed block, a red laser spot is generated after the laser proofer is electrified to irradiate a corner position on the building energy-saving engineering support column, the threaded sleeving connecting plate drives the linkage V-shaped plate to enable the corner positioning plate to move, the inner wall of the corner positioning plate can be contacted with the corner line position of the building energy-saving engineering support column, the four perpendicularity sensors can be respectively positioned at the four face positions of the building energy-saving engineering support column, a plurality of detection orientations are rapidly positioned, and the detection efficiency is effectively improved;
according to the invention, the speed reduction linkage motor is started to drive positively by the adjusting component pressing the controller, the bidirectional screw rod rotates in the guide frame plate, the guide frame plate moves forward in the bidirectional screw rod, the second threaded sleeve joint block moves backward in the guide frame plate, the linkage support plate drives the linkage support column to move forward, the linkage support column drives the semicircular support column to move forward, a larger gap can be opened between the semicircular support column and the connecting support column to be separated from the building energy-saving engineering support column, the semicircular support column and the connecting support column move to the positions on two sides of the next building energy-saving engineering support column, the semicircular support column and the connecting support column can be close together to continue to detect the next building energy-saving engineering support column, and the semicircular support column is separated from the building energy-saving engineering support column or is connected with the building energy-saving engineering support column more efficiently in the later period, so that the detection efficiency is improved;
through the mutual influence of a plurality of structures, can the inner wall contact building energy-saving engineering support column corner line position department through the turning locating plate at first, the rethread makes four straightness sensors of perpendicularity accurate butt joint to building energy-saving engineering support column four detect the face on, can open great space and building energy-saving engineering support column separation between the semicircle branch strip and the connection branch strip at last, can synchronous automatic accurate butt joint a plurality of detection positions in conclusion, accomplish synchronous automated inspection, improve detection efficiency.
Drawings
Fig. 1 is a schematic diagram of the overall structure of a verticality detector of a quality detector for building energy-saving engineering.
Fig. 2 is a schematic diagram of a vertical section structure of a verticality detector of a quality detector for building energy-saving engineering.
Fig. 3 is a schematic view of a local structure of a vertical section at the joint of a semicircular support bar and a sliding concave column in the verticality detector of the quality detector for building energy-saving engineering.
Fig. 4 is a schematic view of a vertical section truncated partial structure of a linkage sleeve joint plate and a guide support frame in a verticality detector of a quality detector for building energy-saving engineering.
Fig. 5 is an enlarged schematic view of the structure of fig. 3 a according to the present invention.
Fig. 6 is a schematic diagram of a positioning assembly in a verticality detector of a quality detector for building energy-saving engineering.
Fig. 7 is a schematic diagram of a top view structure of an adjusting component in a verticality detector of a quality detector for building energy-saving engineering.
Fig. 8 is a schematic diagram of a front view structure of an adjusting component in a verticality detector of a quality detector for building energy-saving engineering.
The reference numerals are: 1. semicircular branch strips; 2. connecting branch bars; 3. sliding concave columns; 4. tilting the hinge rod; 5. a support shaft; 6. a concave sleeve joint block; 7. a linkage screw; 8. a guide support frame; 9. a reduction driving motor; 10. a linkage sleeve joint plate; 11. a perpendicularity sensor; 12. sleeving the linkage block; 13. the thread is sleeved with the supporting block; 14. a distance sensor; 15. a lead drive screw; 16. a servo drive motor; 17. adjusting a frame plate; 18. adjusting a screw; 19. a threaded sleeve joint plate; 20. a linkage V-shaped plate; 21. a corner locating plate; 22. sleeving a fixed block; 23. a laser proofreader; 24. a linkage strut; 25. a linkage support plate; 26. a first threaded socket block; 27. the second thread sleeve joint block; 28. a bidirectional screw; 29. a guide frame plate; 30. a deceleration linkage motor; 31. a grip; 32. and a controller.
Detailed Description
The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.
The utility model provides a building energy-saving engineering quality detector straightness detector that hangs down that is shown as fig. 1-8 is provided with linkage detection mechanism, locating component, adjusting component on this building energy-saving engineering quality detector straightness detector that hangs down, and the setting of each mechanism and subassembly can synchronous automatic accurate butt joint a plurality of detection azimuth, accomplishes synchronous automated inspection, improves detection efficiency, and the specific structure setting of each mechanism and subassembly is as follows:
in some embodiments, as shown in fig. 1-5, the interiors of the connecting branch bar 2 and the semicircular branch bar 1 are both connected with two sliding concave columns 3 in a sliding manner, and a linkage detection mechanism is arranged in the sliding concave columns 3;
the linkage detection mechanism comprises an inclined hinging rod 4 arranged inside a sliding concave column 3, a supporting shaft 5 is arranged on the inner wall of the inclined hinging rod 4 and close to the top end of the inclined hinging rod, a concave sleeving block 6 is fixedly connected to one end of the supporting shaft 5, a linkage screw rod 7 is connected to the inner thread of the concave sleeving block 6, a guiding support frame 8 is connected to the outer wall of the concave sleeving block 6 in a sliding mode, a speed reduction driving motor 9 is connected to the top end of the linkage screw rod 7 in a coaxial transmission mode, a linkage sleeving plate 10 is fixedly connected to one end of the sliding concave column 3, and a perpendicularity sensor 11 is fixedly connected to one end of the linkage sleeving plate 10.
In some embodiments, as shown in the drawings, the outer wall of the perpendicularity sensor 11 is fixedly connected with a sleeving linkage block 12, one side of the perpendicularity sensor 11 is provided with a distance sensor 14 fixedly connected with the sleeving linkage block 12, the top end of the sleeving linkage block 12 is welded with a threaded sleeving support block 13, the inner thread of the threaded sleeving support block 13 is connected with a guide transmission screw 15, the top end of the guide transmission screw 15 is coaxially connected with a servo driving motor 16 in a transmission manner so as to start four servo driving motors 16, the servo driving motor 16 drives the guide transmission screw 15 to rotate in the linkage sleeving plate 10, the threaded sleeving support block 13 moves upwards in the linkage sleeving plate 10 in a guiding manner, the threaded sleeving support block 13 drives the sleeving linkage block 12 to enable the perpendicularity sensor 11 to move upwards, the perpendicularity sensor 11 moves upwards along the detection surface of the building energy-saving engineering support column, automatic detection can be realized on a plurality of detection surfaces of the building energy-saving engineering support column at the same time, and the detection efficiency is effectively improved.
In some embodiments, as shown in fig. 1-6, an adjusting frame plate 17 is fixedly connected to the top end of the semicircular supporting strip 1 and located between two guiding supporting frames 8, a positioning assembly is arranged in the adjusting frame plate 17, the positioning assembly comprises an adjusting screw 18 arranged in the adjusting frame plate 17, a threaded sleeve connecting plate 19 is connected to the outer wall of the adjusting screw 18 in a threaded mode, a linkage V-shaped plate 20 is welded to the top end of the threaded sleeve connecting plate 19, a corner positioning plate 21 is fixedly connected to the inner wall of the linkage V-shaped plate 20, a sleeve connecting fixing block 22 is fixedly connected to the top end of the corner positioning plate 21, a laser calibration device 23 is fixedly connected to the inner portion of the sleeve connecting block 22, and a sliding connection is arranged between the threaded sleeve connecting plate 19 and the adjusting frame plate 17, and the cross section of the corner positioning plate 21 is L-shaped.
In some embodiments, as shown in fig. 1-8, two linkage struts 24 are installed above the connection position of the connection strut 2 and the semicircular strut 1, the two linkage struts 24 are fixedly connected with the semicircular strut 1 and the connection strut 2 in a one-to-one correspondence manner, the top end of the linkage strut 24 is fixedly connected with a linkage strut 25, one side of the linkage strut 24 is provided with a first threaded sleeve block 26 fixedly connected with the linkage strut 25, one side of the first threaded sleeve block 26 is provided with a second threaded sleeve block 27, the inside thread of the second threaded sleeve block 27 is connected with a bidirectional screw rod 28, the outer wall of the first threaded sleeve block 26 is slidably connected with a guide frame plate 29, one end part of the bidirectional screw rod 28 is coaxially connected with a speed reduction linkage motor 30, one side of the guide strut 8 is fixedly connected with two handles 31, a controller 32 is arranged between the two handles 31, the second threaded sleeve block 27 is in threaded connection with the bidirectional screw rod 28, two threads on the outer wall of the bidirectional screw rod 28 are oppositely and symmetrically arranged, the speed reduction motor 30 and the controller 32 are fixedly connected with the guide frame 29, and the second threaded sleeve block 27 is slidably connected with the guide frame 29.
The working principle of the perpendicularity detector of the quality detector of the building energy-saving engineering is as follows:
firstly, when the invention is positioned, a laser corrector 23 sleeved in the fixed block 22 is opened, a red laser spot is generated after the laser corrector 23 is electrified to irradiate a corner position on a building energy-saving engineering support column, an adjusting screw 18 is rotated in the adjusting frame plate 17 according to the laser spot of the laser corrector 23, a thread sleeved plate 19 slides along the adjusting frame plate 17 under the action of threads in a guiding way, the thread sleeved plate 19 drives a linkage V-shaped plate 20 to enable the corner positioning plate 21 to move, the inner wall of the corner positioning plate 21 can contact the corner line position of the building energy-saving engineering support column, the corner positioning plate 21 can accurately position the corner position of the building energy-saving engineering support column, and the four perpendicularity sensors 11 can be respectively positioned at four surface positions of the building energy-saving engineering support column;
secondly, in synchronous detection, by starting four deceleration driving motors 9, the deceleration driving motors 9 drive the linkage screw rods 7 to rotate in the guide support frame 8, the linkage screw rods 7 drive the concave sleeving blocks 6 to move upwards along the guide support frame 8 under the action of threads, the concave sleeving blocks 6 drive the support shafts 5 to move upwards, the support shafts 5 drive the inclined hinging rods 4 to move upwards, the inclined hinging rods 4 drive the sliding concave columns 3 to move from the interiors of the semicircular support strips 1, the other two sliding concave columns 3 can move from the interiors of the connecting support strips 2, the sliding concave columns 3 drive the linkage sleeving plates 10 to move, the linkage sleeving plates 10 drive the perpendicularity sensors 11 to move, the perpendicularity sensors 11 drive the sleeving linkage blocks 12 to enable the distance sensors 14 to move, the distance sensors 14 sense the supporting columns of the building energy-saving engineering, when the distance sensed by the distance sensors 14 reaches 1CM with the distance set by the controller 32, the sleeving linkage block 12 drives the verticality sensor 11 to contact with the detection surface of the building energy-saving engineering support column, the end part of the verticality sensor 11 is extruded and contracted, the four verticality sensors 11 can be accurately abutted on the four detection surfaces of the building energy-saving engineering support column, the four servo driving motors 16 are started, the servo driving motors 16 drive the guide driving screw 15 to rotate in the linkage sleeving plate 10, the guide driving screw 15 drives the screw sleeving support block 13 to move upwards in the linkage sleeving plate 10, meanwhile, the screw sleeving support block 13 drives the sleeving linkage block 12 to enable the verticality sensor 11 to move upwards, the verticality sensor 11 moves upwards along the detection surface of the building energy-saving engineering support column to detect, the verticality sensor 11 can detect whether the detection surface of the building energy-saving engineering support column generates offset amplitude, if the data detected by the perpendicularity sensor 11 does not float, the perpendicularity of the detection surface of the support column of the building energy-saving engineering is qualified, and if the data detected by the perpendicularity sensor 11 float and exceeds the range, the perpendicularity of the detection surface of the support column of the building energy-saving engineering is not qualified;
finally, when the invention is adjusted and separated, the controller 32 is pressed to start the speed-reducing linkage motor 30 to drive forward, two hands respectively hold the two handles 31, the speed-reducing linkage motor 30 drives the bidirectional screw rod 28 to rotate in the guide frame plate 29, the guide frame plate 29 moves forward in the bidirectional screw rod 28, the second threaded sleeve block 27 moves backward in the guide frame plate 29, thus the first threaded sleeve block 26 drives the linkage support plate 25 to move forward, the linkage support plate 25 drives the linkage support column 24 to move forward, the linkage support column 24 drives the semicircular support column 1 to move forward, the other linkage support column 24 drives the connecting support column 2 to move backward, a larger gap can be opened between the semicircular support column 1 and the connecting support column 2, the semicircular support column 1 and the connecting support column 2 are separated from the building energy-saving engineering support column, the semicircular support column 1 and the connecting support column 2 are positioned on two sides of the next building energy-saving engineering support column, the speed-reducing linkage motor 30 is started to drive the bidirectional screw rod 28 to rotate backward in the guide frame plate 29, the first threaded sleeve block 26 and the second threaded sleeve block 25 drive the linkage support column 24 to move forward, the connecting support column 2 moves backward, the other linkage support column 2 drives the connecting support column 2 to move backward, the semicircular support column 1 and the connecting support column 2 to be connected by the two adjacent to the two support columns, and the two adjacent to the two adjacent support columns are in a relative direction-saving support column 2, and the energy-saving engineering support column 2, and the two support columns are detected by the opposite to each side, and adjacent to the two support columns and 2.
The details not described in detail in the specification belong to the prior art known to those skilled in the art, and model parameters of each electric appliance are not specifically limited and can be determined by using conventional equipment.
The foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and principles of the invention are intended to be included within the scope of the invention.
Claims (8)
1. The utility model provides a building energy-saving engineering quality detector straightness detector that hangs down, includes semicircle branch strip (1), one side of semicircle branch strip (1) is equipped with connects branch strip (2), its characterized in that: the inner parts of the connecting branch strips (2) and the semicircular branch strips (1) are respectively and slidably connected with two sliding concave columns (3), and a linkage detection mechanism is arranged in each sliding concave column (3);
the linkage detection mechanism comprises an inclined hinging rod (4) arranged inside a sliding concave column (3), a supporting shaft (5) is arranged on the inner wall of the inclined hinging rod (4) and close to the top end of the inclined hinging rod, a concave sleeving block (6) is fixedly connected to one end of the supporting shaft (5), a linkage screw rod (7) is connected to the inner thread of the concave sleeving block (6), a guide supporting frame (8) is connected to the outer wall of the concave sleeving block (6) in a sliding mode, a speed reduction driving motor (9) is connected to the top end of the linkage screw rod (7) in a coaxial transmission mode, a linkage sleeving plate (10) is fixedly connected to one end of the sliding concave column (3), and a perpendicularity sensor (11) is fixedly connected to one end of the linkage sleeving plate (10);
the speed reduction driving motor (9) and the semicircular supporting strip (1) are fixedly connected with the guide supporting frame (8), and the semicircular supporting strip (1) and the connecting supporting strip (2) are symmetrically arranged;
the outer wall fixedly connected with of straightness sensor (11) cup joints linkage piece (12), one side of straightness sensor (11) is equipped with and cup joints linkage piece (12) fixed connection's distance sensor (14), cup joints the top welding of linkage piece (12) and has the screw thread to cup joint a piece (13) the inside threaded connection of screw thread cup joints a piece (13) has direction drive screw (15), the coaxial transmission in top of direction drive screw (15) is connected with servo driving motor (16).
2. The detector for perpendicularity of a quality detector for construction energy-saving engineering according to claim 1, wherein: the sliding concave column (3) and the supporting shaft (5) are both rotationally connected with the inclined hinging rod (4), and the sliding concave column (3) and the inclined hinging rod (4) are both made of stainless steel materials.
3. The detector for perpendicularity of a quality detector for construction energy-saving engineering according to claim 1, wherein: the screw sleeve joint support block (13) is in sliding connection with the linkage sleeve joint plate (10), and the servo driving motor (16) is fixedly connected with the linkage sleeve joint plate (10).
4. The detector for perpendicularity of a quality detector for construction energy-saving engineering according to claim 1, wherein: the semicircular branch strip comprises a semicircular branch strip body (1), wherein the top end of the semicircular branch strip body is fixedly connected with an adjusting frame plate (17) between two guiding branch frames (8), a positioning assembly is arranged in the adjusting frame plate (17), the positioning assembly comprises an adjusting screw rod (18) arranged in the adjusting frame plate (17), a threaded sleeve connecting plate (19) is connected to the outer wall of the adjusting screw rod (18) in a threaded mode, a linkage V-shaped plate (20) is welded to the top end of the threaded sleeve connecting plate (19), a corner positioning plate (21) is fixedly connected to the inner wall of the linkage V-shaped plate (20), a sleeve fixing block (22) is fixedly connected to the top end of the corner positioning plate (21), and a laser calibrator (23) is fixedly connected to the inner side of the sleeve fixing block (22).
5. The detector for perpendicularity of a quality detector for construction energy-saving engineering according to claim 4, wherein: the threaded sleeve connection plate (19) is in sliding connection with the adjusting frame plate (17), and the cross section of the corner positioning plate (21) is L-shaped.
6. The detector for perpendicularity of a quality detector for construction energy-saving engineering according to claim 1, wherein: two linkage struts (24) are installed to connection branch (2) and semicircle branch (1) junction top, two linkage struts (24) respectively with semicircle branch (1) and connection branch (2) one-to-one fixed connection, the top of linkage struts (24) is connected with adjusting part, adjusting part includes linkage extension board (25) of fixed connection on linkage struts (24) top, one side of linkage struts (24) is equipped with first screw thread nipple (26) with linkage extension board (25) fixed connection, one side of first screw thread nipple (26) is equipped with second screw thread nipple (27), the internal thread connection of second screw thread nipple (27) has bi-directional screw rod (28), the outer wall sliding connection of first screw thread nipple (26) has deflector (29), the coaxial transmission of one end of bi-directional screw rod (28) is connected with speed reduction linkage motor (30), one side of deflector frame (8) is fixedly connected with two grip (31), two grip (32) are equipped with between controller (31).
7. The detector for perpendicularity of a quality detector for construction energy saving engineering according to claim 6, wherein: the second threaded sleeve joint block (27) is in threaded connection with the bidirectional screw rod (28), and two threads on the outer wall of the bidirectional screw rod (28) are opposite and symmetrically arranged.
8. The detector for perpendicularity of a quality detector for construction energy saving engineering according to claim 6, wherein: the speed reduction linkage motor (30) and the controller (32) are fixedly connected with the guide frame plate (29), and the second threaded sleeve joint block (27) is slidably connected with the guide frame plate (29).
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| CN202311570302.8A CN117516476B (en) | 2023-11-23 | 2023-11-23 | Verticality detector for quality detector of building energy-saving engineering |
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| CN117516476B (en) | 2024-03-22 |
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