CN112611359A - Building verticality measuring device - Google Patents

Abstract

The invention relates to a measuring device, in particular to a building verticality measuring device. The technical problem to be solved by the invention is as follows: the building verticality measuring device capable of automatically paying off and measuring verticality is provided. A building verticality measuring device comprises: installing a frame; the wheels are symmetrically and rotatably arranged on two sides of the mounting frame; the power assembly is arranged on the mounting frame; the lifting assembly is arranged on the mounting frame; the winding assembly is arranged on the mounting frame; and the measuring assembly is arranged on the mounting frame. The invention is provided with wheels, which is convenient for moving the device and reduces the physical power consumed by moving the device when a worker measures; the invention is provided with the lifting assembly and the telescopic assembly, can measure the inclination of the wall surface in different degrees, and fixes the height, so that the measurement is more accurate; the invention is provided with the fixing component, so that the conical block is prevented from shaking by the moving device when not measuring, and the conical block can be effectively prevented from hurting people.

Description

Building verticality measuring device

Technical Field

The invention relates to a measuring device, in particular to a building verticality measuring device.

Background

Perpendicularity measurement is a condition that a measured element on a part maintains a correct 90-degree included angle relative to a reference element. I.e. the degree to which orthogonality between the two elements is maintained. The elements of perpendicularity are generally straight lines and planes. Perpendicularity evaluates the perpendicular state between straight lines, between planes, or between straight lines and planes. Perpendicularity is often measured in buildings.

At present, the verticality of a building is measured manually. During the measurement, the staff is holding the plummet, utilizes the perpendicularity of the structure of comparing from the perpendicular of plummet to measure, selects unwrapping wire under the weather of no wind, and the weight of hammerhead will be changed at any time according to the height, and then the reuse steel rule is measured, and not only the easy emergence is skew during artifical measurement, and comparatively slight deviation measurement can not go out moreover, leads to measuring inaccurately.

Therefore, it is necessary to design a building verticality measuring device capable of automatically paying off and measuring verticality.

Disclosure of Invention

In order to overcome the defects that the measurement of the deviation of the verticality of the building which is measured slightly at present cannot be carried out and the measurement is inaccurate, the technical problem is as follows: the building verticality measuring device capable of automatically paying off and measuring verticality is provided.

The technical scheme of the invention is as follows: a building verticality measuring device comprises: installing a frame; the wheels are symmetrically and rotatably arranged on two sides of the mounting frame; the power assembly is arranged on the mounting frame; the lifting assembly is arranged on the mounting frame; the winding assembly is arranged on the mounting frame; and the measuring assembly is arranged on the mounting frame.

Further, the power assembly comprises: the telescopic rotating shaft is rotatably arranged on the mounting frame; the hand wheel is arranged on the telescopic rotating shaft; and the first bevel gear is arranged on the telescopic rotating shaft.

Further, the lifting assembly comprises: the screw rod is rotatably arranged on the mounting frame; the second bevel gear is arranged on the screw rod; the threaded sleeve is arranged on the screw rod; the support is arranged on the grain sleeve.

Further, the winding assembly comprises: the rotating rod is rotatably arranged on the mounting frame; a reel mounted on the rotary rod; a stay mounted on the reel; the transmission belt pulley group is arranged between the rotating rod and the telescopic rotating shaft; the fixed pulleys are rotatably arranged on two sides of the bracket, and the tail end of the stay wire is wound around the fixed pulleys on the two sides; the conical block is arranged at the tail end of the stay wire.

Further, the measuring assembly comprises: the first mounting plate is mounted on the mounting frame; the first guide rod is arranged between the mounting frame and the first mounting plate; the first sliding rail with scales is slidably arranged on the first mounting plate; the first spring is arranged between the first guide rod and the first sliding track; the first wire guide sleeve is slidably mounted on the first sliding track, and the pull wire penetrates through the first wire guide sleeve; the mounting block is mounted on the bracket; the second mounting plate is mounted on the mounting block; the second guide rod is arranged between the second mounting plate and the threaded sleeve; the second sliding rail with scales is slidably arranged on the second mounting plate; the second spring is arranged between the second guide rod and the second sliding track; and the second wire guide sleeve is slidably mounted on the second sliding track, and the pull wire penetrates through the second wire guide sleeve.

Further, still including flexible subassembly, flexible subassembly is including: a hollow bar installed on the first guide bar; the bolt is arranged on the hollow rod through threads; and the lifting rod is arranged on the second guide rod and is connected with the hollow rod in a sliding manner, and the lifting rod is matched with the bolt.

Further, still including fixed subassembly, fixed subassembly is including: the third guide rod is arranged on the mounting frame; the arc-shaped fixture block is slidably arranged on the third guide rod; the clamping plate is rotatably arranged on the arc-shaped clamping block; and the wedge-shaped clamping blocks are arranged on two sides of the third guide rod in a sliding manner.

The beneficial effects are that: 1. the invention is provided with wheels, which is convenient for moving the device and reduces the physical power consumed by moving the device when a worker measures;

2. the invention is provided with the lifting assembly and the telescopic assembly, can measure the inclination of the wall surface in different degrees, and fixes the height, so that the measurement is more accurate;

3. the invention is provided with the fixing component, so that the conical block is prevented from shaking by the moving device when not measuring, and the conical block can be effectively prevented from hurting workers.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a partial perspective view of the present invention.

Fig. 3 is a schematic perspective view of the power module of the present invention.

Fig. 4 is a schematic perspective view of the lifting assembly of the present invention.

Fig. 5 is a schematic perspective view of the winding assembly of the present invention.

FIG. 6 is a schematic view of a first partially separated body structure of a measurement assembly of the present invention.

FIG. 7 is a schematic view of a second partially separated body structure of the measurement assembly of the present invention.

Fig. 8 is a perspective view of the telescopic assembly of the present invention.

Fig. 9 is a perspective view of the fixing member of the present invention.

In the reference symbols: 1_ mounting frame, 2_ wheel, 3_ power assembly, 31_ telescopic rotating shaft, 32_ hand wheel, 33_ first bevel gear, 4_ lifting assembly, 41_ lead screw, 42_ second bevel gear, 43_ thread bush, 44_ bracket, 5_ winding assembly, 51_ rotating rod, 52_ reel, 53_ pull wire, 54_ driving pulley set, 55_ fixed pulley, 56_ conical block, 6_ measuring assembly, 61_ first guide rod, 62_ first spring, 63_ first mounting plate, 64_ first sliding track, 65_ first guide sleeve, 66_ second guide rod, 67_ second spring, 68_ mounting block, 69_ second mounting plate, 610_ second sliding track, 611_ second guide sleeve, 7_ telescopic assembly, 71_ hollow rod, 72_ bolt, 73_ lifting rod, 8_ fixing assembly, 81_ third guide rod, 82_ arc fixture block, 83_ clamping plate, 84_ wedge block.

Detailed Description

The preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Example 1

The utility model provides a building straightness measuring device that hangs down, as shown in fig. 1-7, including installing frame 1, wheel 2, power component 3, lifting unit 4, wire winding subassembly 5 and measuring unit 6, the equal front and back symmetry's of the lower part left and right sides of installing frame 1 rotary type is equipped with wheel 2, the inside of installing frame 1 is equipped with power component 3, lifting unit 4 is installed to the upside of installing frame 1, is equipped with wire winding subassembly 5 on the installing frame 1, measuring unit 6 is installed on the right side of installing frame 1.

When needs measure the building straightness that hangs down, roll through wheel 2 and remove the device to the wall, manual control power component 3 is adjusted lifting unit 4 and winding components 5, stops controlling power component 3 after adjusting and then places measuring component 6 on the wall, then sees measuring component 6 and just can measure the building straightness that hangs down, when the measurement is accomplished, controls power component 3 reverse operation for above-mentioned part resets, then stops to control power component 3.

The power assembly 3 comprises a telescopic rotating shaft 31, a hand wheel 32 and a first bevel gear 33, the telescopic rotating shaft 31 is rotatably installed on the inner side of the installation frame 1, the hand wheel 32 is welded on the front side of the telescopic rotating shaft 31 after penetrating through the installation frame 1, and the first bevel gear 33 is in keyed connection with the telescopic rotating shaft 31.

When the straightness that hangs down of building is measured to needs, remove the device to the wall, hand rotation hand wheel 32, make flexible axis of rotation 31 rotate, thereby make winding assembly 5 operate, still can drive first bevel gear 33 simultaneously and rotate, thereby drive lifting unit 4 and operate, when not needing lifting unit 4 to operate, pulling hand wheel 32, make first bevel gear 33 not mesh with lifting unit 4, adjust the back, stop rotating hand wheel 32, when measuring the completion, control hand wheel 32 reverses, make above-mentioned part reset, then stop control hand wheel 32.

Lifting unit 4 is including lead screw 41, second bevel gear 42, thread bush 43 and support 44, and lead screw 41 is installed through the bearing frame rotary type to the upside of installing frame 1, and the downside key-type of lead screw 41 has second bevel gear 42, installs thread bush 43 through the screw on the lead screw 41, and thread bush 43 and installing frame 1 sliding fit, the upside of thread bush 43 has support 44 through the screw rigid coupling.

The hand wheel 32 is rotated manually to drive the first bevel gear 33 to rotate, so as to drive the second bevel gear 42 to rotate, so as to drive the screw rod 41 to rotate, so that the threaded sleeve 43 moves upwards to drive the bracket 44 to move upwards, and when the hand wheel 32 stops rotating, the operation of the lifting assembly 4 stops.

The winding assembly 5 comprises a rotary rod 51, a winding wheel 52, a stay wire 53, a transmission belt pulley set 54, a fixed pulley 55 and a conical block 56, the rotary rod 51 is rotatably installed on the left side inside the installation frame 1, the winding wheel 52 is installed in the middle of the rotary rod 51, the stay wire 53 is wound on the winding wheel 52, the transmission belt pulley set 54 is connected between the rear side of the rotary rod 51 and the rear side of the telescopic rotating shaft 31, the fixed pulleys 55 are rotatably arranged on the left side and the right side of the support 44, and the tail end of the stay wire 53 is connected with the conical block 56 by bypassing the fixed pulleys 55 on the two sides.

The hand wheel 32 is manually rotated, so that the telescopic rotating shaft 31 rotates, the transmission belt pulley group 54 rotates, the rotating rod 51 rotates, the reel 52 is driven to rotate, the pull wire 53 controls the conical block 56 to move, and after the conical block 56 moves to a proper position, the hand wheel 32 is stopped to be controlled, and the winding assembly 5 stops operating.

The measuring assembly 6 comprises a first guide rod 61, a first spring 62, a first mounting plate 63, a first sliding rail 64, a first wire guide sleeve 65, a second guide rod 66, a second spring 67, a mounting block 68, a second mounting plate 69, a second sliding rail 610 and a second wire guide sleeve 611, wherein the first mounting plate 63 is mounted on the upper right side of the mounting frame 1, the first guide rod 61 is mounted between the mounting frame 1 and the left side of the first mounting plate 63, the first sliding rail 64 with scales is slidably mounted on the first mounting plate 63, the first sliding rail 64 is slidably matched with the first guide rod 61, the first spring 62 is connected between the first guide rod 61 and the first sliding rail 64, the first wire guide sleeve 65 is slidably arranged on the first sliding rail 64, the pull wire 53 penetrates through the first wire guide sleeve 65, the mounting block 68 is fixedly connected to the lower right side of the right portion of the bracket 44 through a fixing screw, the second mounting plate 69 is connected to the right side of the mounting block 68, a second guide rod 66 is connected between the second mounting plate 69 and the threaded sleeve 43, a second sliding rail 610 with scales is slidably mounted on the second mounting plate 69, the second sliding rail 610 is slidably matched with the second guide rod 66, a second spring 67 is connected between the second guide rod 66 and the left side of the second sliding rail 610, a second wire guide sleeve 611 is slidably arranged on the second sliding rail 610, and the pull wire 53 penetrates through the second wire guide sleeve 611.

When the verticality of the building needs to be measured, the device is pushed to the place to be measured, when the ground of the building inclines, the conical block 56 and the pull wire 53 are not perpendicular to the ground of the building, the position of the first wire sleeve 65 in the first sliding track 64 is different from the position of the second wire sleeve 611 in the second sliding track 610, when the ground of the building does not incline, the conical block 56 and the pull wire 53 are perpendicular to the ground of the building, the position of the first wire sleeve 65 in the first sliding track 64 is the same as the position of the second wire sleeve 611 in the second sliding track 610, after the ground is measured, the first sliding track 64 and the second sliding track 610 are contacted with the wall surface, the first spring 62 and the second spring 67 are compressed, when the wall surface is perpendicular to the ground, the position of the first wire sleeve 65 in the first sliding track 64 is the same as the position of the second wire sleeve 611 in the second sliding track 610, when the wall surface is not perpendicular to the ground, the position of the first wire guide sleeve 65 in the first slide rail 64 and the position of the second wire guide sleeve 611 in the second slide rail 610 may be different, and then the magnitude of the inclination angle is seen from the scales in the first slide rail 64 and the second slide rail 610.

Example 2

On the basis of embodiment 1, as shown in fig. 1, 8 and 9, the telescopic assembly 7 is further included, the telescopic assembly 7 includes a hollow rod 71, a bolt 72 and a lifting rod 73, the left side of the first guide rod 61 is connected with the hollow rod 71, the bolt 72 is connected to the hollow rod 71 through a thread, the lifting rod 73 is connected to the left side of the second guide rod 66, the lifting rod 73 is connected with the hollow rod 71 in a sliding manner, and the lifting rod 73 is matched with the bolt 72.

When adjusting the position of thread bush 43, can drive lifter 73 and remove in hollow pole 71, adjust the position after, screw up bolt 72 with the hand to make bolt 72 and lifter 73 cooperation, make lifter 73 fix, thereby prevent the change of thread bush 43 position, when need not to use, alright unscrew bolt 72, be convenient for use next time.

Still including fixed subassembly 8, fixed subassembly 8 is connected with third guide arm 81 including third guide arm 81, arc fixture block 82, cardboard 83 and wedge fixture block 84 on the right side of installing frame 1, and the last slip type of third guide arm 81 is connected with arc fixture block 82, and the right side rotary type of arc fixture block 82 is connected with cardboard 83, and two wedge fixture blocks 84 about the upside slip type of third guide arm 81 is installed.

When the perpendicularity of the building is measured, the clamping plate 83 is rotated to loosen the conical block 56 and put into the arc-shaped clamping block 82, then the arc-shaped clamping block 82 is moved to the wedge-shaped clamping block 84, the wedge-shaped clamping block 84 can be matched with the arc-shaped clamping block 82, the arc-shaped clamping block 82 is clamped, the conical block 56 is fixed, and the conical block 56 is prevented from shaking to hurt people.

While the disclosure has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the disclosure as defined by the appended claims and their equivalents. Accordingly, the scope of the present disclosure should not be limited to the above-described embodiments, but should be defined not only by the appended claims, but also by equivalents thereof.

Claims (7)

1. A building verticality measuring device is characterized by comprising:

an installation frame (1);

the wheels (2) are symmetrically and rotatably arranged on two sides of the mounting frame (1);

the power assembly (3) is arranged on the mounting frame (1);

the lifting component (4) is arranged on the mounting frame (1);

the winding assembly (5) is installed on the installation frame (1);

and the measuring assembly (6) is installed on the installation frame (1).

2. A building perpendicularity measuring device according to claim 1, wherein the power unit (3) comprises:

the telescopic rotating shaft (31) is rotatably arranged on the mounting frame (1);

a hand wheel (32) mounted on the telescopic rotating shaft (31);

and a first bevel gear (33) mounted on the telescopic rotating shaft (31).

3. A building perpendicularity measuring device according to claim 2, characterized in that the lifting unit (4) comprises:

the screw rod (41) is rotatably arranged on the mounting frame (1);

a second bevel gear (42) mounted on the screw rod (41);

a threaded sleeve (43) mounted on the screw rod (41);

and the bracket (44) is arranged on the threaded sleeve (43).

4. A building perpendicularity measuring device according to claim 3, wherein the winding assembly (5) includes:

the rotating rod (51) is rotatably arranged on the mounting frame (1);

a reel (52) mounted on the rotary rod (51);

a pull-out wire (53) attached to the reel (52);

a transmission belt pulley group (54) arranged between the rotating rod (51) and the telescopic rotating shaft (31);

the fixed pulleys (55) are rotatably arranged on two sides of the bracket (44), and the tail end (53) of the stay wire rounds the fixed pulleys (55) on the two sides;

and a tapered block (56) mounted on the rear end of the wire (53).

5. Device according to claim 4, characterized in that said measuring unit (6) comprises:

a first mounting plate (63) mounted on the mounting frame (1);

a first guide rod (61) installed between the installation frame (1) and the first installation plate (63);

the first sliding rail (64) with scales is slidably arranged on the first mounting plate (63);

a first spring (62) installed between the first guide bar (61) and the first slide rail (64);

a first wire guide sleeve (65) which is slidably mounted on the first sliding rail (64), and the pull wire (53) passes through the first wire guide sleeve (65);

a mounting block (68) mounted on the bracket (44);

a second mounting plate (69) mounted on the mounting block (68);

a second guide rod (66) installed between the second installation plate (69) and the threaded sleeve (43);

the second sliding rail (610) with scales is slidably mounted on the second mounting plate (69);

a second spring (67) installed between the second guide bar (66) and the second slide rail (610);

and a second wire guide sleeve (611) which is slidably mounted on the second sliding rail (610), wherein the pull wire (53) passes through the second wire guide sleeve (611).

6. A building perpendicularity measuring device according to claim 5, characterized by further comprising a telescopic assembly (7), wherein the telescopic assembly (7) comprises:

a hollow bar (71) mounted on the first guide bar (61);

a bolt (72) which is mounted on the hollow bar (71) by a screw thread;

and the lifting rod (73) is arranged on the second guide rod (66), the lifting rod (73) is connected with the hollow rod (71) in a sliding manner, and the lifting rod (73) is matched with the bolt (72).

7. A building perpendicularity measuring device according to claim 6, further comprising a fixing member (8), wherein the fixing member (8) comprises:

a third guide rod (81) mounted on the mounting frame (1);

the arc-shaped fixture block (82) is slidably mounted on the third guide rod (81);

the clamping plate (83) is rotatably arranged on the arc-shaped clamping block (82);

and wedge-shaped fixture blocks (84) are slidably arranged on two sides of the third guide rod (81).

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