CN113587771B - Super high-rise building engineering measuring equipment - Google Patents

Abstract

The invention relates to the field of constructional engineering, in particular to super high-rise constructional engineering measuring equipment, which comprises: a bottom plate; the lifting assembly is connected with the bottom plate; the swing assembly is connected to the lifting assembly; wherein, swing subassembly includes: the supporting groove is connected with the lifting assembly, and the steering mechanism is arranged in the supporting groove and is connected with the supporting groove; and the measuring assembly is connected with the swinging assembly and is used for accurately measuring the high-rise building. According to the super high-rise building engineering measuring equipment, the equipment is firstly required to be conveyed to a designated position, then the lifting assembly is started, the measuring assembly is lifted to the height to be measured, then the swinging assembly is started, and the direction of the measuring assembly is adjusted, so that the measurement is more conveniently carried out, after the adjustment is finished, the measuring assembly is started to carry out the measurement, the measuring process is simplified, the measurement is avoided from being carried out manually to a high place, the potential safety hazard is reduced, and the practicability is strong.

Description

Super high-rise building engineering measuring equipment

Technical Field

The invention relates to the field of constructional engineering, in particular to ultra-high-rise constructional engineering measuring equipment.

Background

When building, in order to maximize the utilization rate of land, multiple layers of buildings are often formed, so that a modern high-rise building is formed, and in order to ensure the stability of the building, the building planning of engineers is very important.

When the existing super high-rise building is used for measuring, the measurement is often needed to be carried out manually to a high place, the difficulty is high, and a certain risk exists, so that the super high-rise building engineering measuring equipment is needed to solve the problems.

Disclosure of Invention

The embodiment of the invention aims to provide super high-rise building engineering measuring equipment, which aims to solve the following problems: the existing high-rise building is not easy to measure.

The embodiment of the invention is realized in such a way that the ultra-high-rise building engineering measuring equipment comprises: a bottom plate; the lifting assembly is connected with the bottom plate and used for lifting the equipment to a set height; the swing assembly is connected to the lifting assembly and is used for rotating in the horizontal direction to adjust the measuring direction; wherein, swing subassembly includes: the supporting groove is connected with the lifting assembly, and the steering mechanism is arranged in the supporting groove and is connected with the supporting groove; and the measuring assembly is connected with the swinging assembly and is used for accurately measuring the high-rise building.

Preferably, the lifting assembly comprises: the supporting seat is connected with the bottom plate through a supporting rod; one end of the vertical rod is fixed on the supporting seat and is used for providing guidance for equipment in the process of lifting the equipment; the top plate is connected with the other end of the vertical rod and used for limiting the rising height and blocking rainwater; the power mechanism is connected to one side of the supporting seat, which is far away from the bottom plate, and is used for providing power support for the ascending process of the measuring assembly; and the lifting mechanism is connected with the power mechanism and used for lifting to transport the measuring assembly to a set height.

Preferably, the power mechanism includes: one end of the limiting rod is connected to the vertical rod; the base is sleeved in the limit rotating rod and can slide on the limit rotating rod; the driving piece is fixed on one side of the base and matched with the limiting rod, and is used for preventing the driving piece from rotating when working; the sleeve joint piece is sleeved on the central shaft of the driving piece and can rotate on the central shaft of the driving piece; the guide gear is fixed with one end of the central shaft of the driving piece; and the guide rack is meshed with the guide gear and is fixed on the supporting seat and used for driving the lifting mechanism to move upwards.

Preferably, the lifting mechanism comprises: one end of the first sliding rod is connected with the vertical rod; the first sliding piece is in sliding sleeve joint with the first sliding rod and can freely slide on the first sliding rod; a first hinge lever having one end hinged with the first slider; the lifting plate is hinged to the first hinging rod and provided with a groove, and is fixedly connected with the swinging assembly and used for lifting the swinging assembly and the measuring assembly to a proper height; the second slide bar is connected with a groove formed in the lifting plate; the second sliding piece is sleeved on the second sliding rod and can slide on the second sliding rod; and the two ends of the second hinging rod are respectively hinged with the second sliding piece and the first hinging rod, and the second hinging rod is rotationally connected with the middle part of the first hinging rod.

Preferably, the steering mechanism includes: the guide posts are arranged in the supporting grooves, the two ends of the guide posts are connected with the supporting grooves, and at least two guide posts are arranged; the movable rack is sleeved on the guide post and can slide on the guide post; a rotating gear meshed with the movable rack; the shaft lever is sleeved on the rotating gear and fixedly connected with the rotating gear; an elastic member fixed between the moving rack and the support groove; the driving part is sleeved on the guide post and used for providing steering power for the shaft lever.

Preferably, the driving part includes: the two ends of the mounting plate are connected with the guide posts; a driving cam mounted on the mounting plate; a roller in contact with the driving cam; and the pressing block is connected with the roller rotating shaft through a connecting rod.

Preferably, the measuring assembly comprises: the side plate is connected with the steering mechanism; the two ends of the threaded rod are rotatably connected to the side plates; the power piece is connected to one end of the threaded rod; the thread block is sleeved on the threaded rod in a threaded manner and forms a screw pair with the threaded rod to rotate; one end of the measuring rod is connected with the thread block; the two ends of the measuring ruler are connected with the measuring rod and are parallel to the measuring rod; the guide block is connected with the other end of the measuring rod; the two ends of the guide rod are fixed on the side plates, and the guide block is sleeved on the guide rod and can slide on the guide rod.

When the super high-rise building engineering measuring equipment is used for measuring, the equipment is firstly required to be conveyed to a designated position, then the lifting assembly is started, the measuring assembly is lifted to the height to be measured, then the swinging assembly is started, the azimuth of the measuring assembly is adjusted, so that the measuring is more conveniently carried out, after the adjustment is finished, the measuring assembly is started for measuring, the measuring process is simplified, the measurement is avoided from being carried out manually to a high place, the potential safety hazard is reduced, and the practicability is strong.

Drawings

Fig. 1 is a schematic structural view of a super high-rise building engineering measuring apparatus.

Fig. 2 is a side view of a power mechanism of the super high-rise building engineering measurement apparatus.

Fig. 3 is a schematic view of a steering mechanism of the super high-rise building engineering measuring device.

Fig. 4 is a schematic diagram of a measuring assembly of the super high-rise building engineering measuring apparatus.

In the accompanying drawings: 1-bottom plate, 2-lifting component, 21-supporting seat, 22-vertical rod, 23-top plate, 24-power mechanism, 241-limit rotating rod, 242-base, 243-driving piece, 244-socket piece, 245-guiding gear, 246-guiding rack, 25-lifting mechanism, 251-first sliding rod, 252-first sliding piece, 253-first hinging rod, 254-lifting plate, 255-second sliding rod, 256-second sliding piece, 257-elastic piece, 258-second hinging rod, 3-swinging component, 4-supporting groove, 5-steering mechanism, 51-guiding column, 52-moving rack, 53-rotating gear, 54-shaft rod, 55-elastic piece, 56-driving component, 561-mounting plate, 562-driving cam, 563-roller, 564-pressing block, 6-measuring component, 61-side plate, 62-threaded rod, 63-power piece, 64-threaded block, 65-measuring rod, 66-ruler, 67-guiding block, 68-guiding rod.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Specific implementations of the invention are described in detail below in connection with specific embodiments.

Referring to fig. 1 and 3, an embodiment of the present invention provides a super high-rise building engineering measurement device, including:

a base plate 1; a lifting assembly 2 connected to the base plate 1 for lifting the apparatus to a set height; a swing assembly 3 connected to the lifting assembly 2 for rotation in a horizontal direction to adjust the measuring orientation; wherein the swing assembly 3 comprises: the support groove 4 is connected with the lifting assembly 2, and the steering mechanism 5 is arranged in the support groove 4 and connected with the support groove 4; and the measuring assembly 6 is connected with the swinging assembly 3 and is used for accurately measuring the high-rise building.

In one embodiment of the invention, when the equipment is used for super high-rise measurement, the equipment is firstly transported to a designated position, then the lifting component 2 is started, the lifting component 2 can drive the swinging mechanism 3 and the measuring component 6 to ascend, when the measuring component 6 ascends to a required height, the lifting component 2 is closed, the steering mechanism 5 is started, the direction of the measuring component 6 is adjusted, and when the measuring component 6 reaches the optimal direction, the measuring component 6 can be started to measure the high-rise building.

As shown in fig. 1, as a preferred embodiment of the present invention, the lifting assembly 2 includes: the supporting seat 21 is connected with the bottom plate 1 through a supporting rod; a vertical rod 22, one end of which is fixed on the supporting seat 21, for providing guidance for the equipment during its lifting; the top plate 23 is connected with the other end of the vertical rod 22 and used for limiting the rising height and blocking rainwater; the power mechanism 24 is connected to one side of the supporting seat 21 away from the bottom plate 1 and is used for providing power support for the ascending process of the measuring assembly 6; and a lifting mechanism 25 connected with the power mechanism 24 for lifting and transporting the measuring assembly 6 to a set height.

In one embodiment of the present invention, when the height of the measuring assembly 6 is adjusted, the power mechanism 24 is started, the power mechanism 24 drives the lifting block of the lifting mechanism 25 to move upwards along the vertical rod 22, and the lifting block is sleeved with the vertical rod 22, so that the lifting mechanism 25 drives the steering mechanism 5 and the measuring assembly 6 to lift.

In this embodiment, to drive the swinging component 3 and the measuring component 6 to rise, various manners may be adopted, as long as the height of the measuring component 6 can be freely adjusted, for example, a hydraulic rod is used to drive the swinging component and the measuring component to rise and fall.

As shown in fig. 1 and 2, as a preferred embodiment of the present invention, the power mechanism 24 includes: a limit lever 241, one end of which is connected to the vertical lever 22; the base 242 is sleeved in the limiting rod 241 and can slide on the limiting rod 241; the driving piece 243 is fixed on one side of the base 242, and the driving piece 243 is matched with the limiting rod 241 and is used for preventing the driving piece 243 from rotating when working; the sleeving piece 244 is sleeved on the central shaft of the driving piece 243 and can rotate on the central shaft of the driving piece 243; a guide gear 245 fixed to one end of the central shaft of the driving member 243; a guide rack 246 engaged with the guide gear 245 and fixed to the support base 21 for driving the elevating mechanism 25 to move upward.

In one embodiment of the present invention, when driving, the driving member 243 is turned on, and the driving member 243 can be specifically driven by a motor or other components, the output shaft of the driving member 243 drives the guide gear 245 to move leftwards or rightwards along the guide rack 246, so as to drive the bottom plate 242 at the bottom of the driving member 243 to move leftwards or rightwards along the limit rotating rod 241, thereby avoiding the driving member 243 from following rotation and smoothly driving the lifting mechanism 25 to lift.

In this embodiment, if the lifting mechanism 25 is to be lifted, the power only needs to control the first sliding member 252 to move rightwards, for example, a motor may be used to drive a threaded rod, and the threaded rod drives a threaded block to move leftwards or rightwards to control the lifting mechanism 25 to lift, and a guide rod is also needed to be added to prevent the threaded block from rotating along with the threaded rod.

As shown in fig. 1, as a preferred embodiment of the present invention, the lifting mechanism 25 includes: one end of the first sliding rod 251 is connected with the vertical rod 22; the first sliding piece 252 is in sliding sleeve joint with the first sliding rod 251, and the first sliding piece 252 can freely slide on the first sliding rod 251; a first hinge lever 253 having one end hinged with the first slider 252; the lifting plate 254 is hinged on the first hinging rod 253 and provided with a groove, and the lifting plate 254 is fixedly connected with the swinging component 3 and is used for lifting the swinging component 3 and the measuring component 6 to a proper height; the second sliding rod 255 is connected with a groove formed in the lifting plate 254; the second sliding piece 256 is sleeved on the second sliding rod 255 and can slide on the second sliding rod 255; and two ends of the second hinging rod 258 are respectively hinged with the second sliding piece 256 and the first hinging rod 253, and the second hinging rod 258 is rotatably connected with the middle part of the first hinging rod 253.

In one embodiment of the present invention, when the height measurement is performed, the first sliding member 252 moves rightward along the sliding rod 251 under the driving of the power mechanism 24, so as to push the lifting plate 254 to move upward, and at the same time, the second sliding member 256 moves upward along the second sliding rod 255, and compresses the elastic member 257, where the elastic member 257 may use a resilient member such as a spring, so as to ensure the stability of the upward movement of the lifting plate 254, and thus drive the measuring assembly 6 to rise to a proper position for measurement.

In this embodiment, if the measuring assembly 6 is to be lifted, various manners, such as using a pulley block to drive, fixing the measuring assembly 6 and the pulley block, and using a motor to drive the pulley block to drive the measuring assembly 6 to lift, may also be used to implement the measuring operation.

As shown in fig. 3, as a preferred embodiment of the present invention, the steering mechanism 5 includes: the guide posts 51 are arranged in the supporting groove 4, two ends of the guide posts are connected with the supporting groove 4, and at least two guide posts 51 are arranged; a movable rack 52 which is sleeved on the guide post 51 and can slide on the guide post 51; a rotation gear 53 engaged with the moving rack 52; the shaft lever 54 is sleeved on the rotating gear 53 and fixedly connected with the rotating gear 53; an elastic member 55 fixed between the moving rack 52 and the support groove 4; a driving part 56 is sleeved on the guide post 51 and is used for providing steering power for the shaft rod 54.

In one embodiment of the present invention, when the steering is performed, the driving member 56 is turned on, the driving member 56 drives the moving rack 52 to move rightward along the guide post 51 and compresses the elastic member 55, and the elastic member 55 may specifically use a return spring, and the rotating gear 53 rotates while the moving rack 52 moves rightward, the rotating gear 53 drives the shaft 54 to rotate, and the shaft 54 rotates to drive the measuring assembly 6 to perform azimuthal rotation in the horizontal direction, so that the optimal measuring position can be adjusted.

In this embodiment, when the azimuth rotation is performed, a plurality of modes can be adopted, and only the azimuth adjustment is needed, for example, a horizontally installed motor is used to drive the measuring assembly 6 to perform azimuth rotation.

As shown in fig. 3, as a preferred embodiment of the present invention, the driving part 56 includes: mounting plate 561, both ends are connected with guide post 51; a drive cam 562 mounted on the mounting plate 51; a roller 563 in contact with the driving cam 562; the pressing block 564 is connected with the rotating shaft of the roller 563 through a connecting rod.

In one embodiment of the present invention, when the driving is performed, the driving cam 562 is turned on, the driving cam 562 drives the roller 563 to move rightward, so as to drive the pressing block 564 to press the moving rack 52 rightward, and simultaneously compress the elastic member 55, when the driving cam 562 continues to rotate, the moving rack 52 can move leftward under the pushing of the elastic member 55, so that the driving cam 562 can be turned off to perform the measurement when the orientation reaches the optimal position.

In this embodiment, an eccentric wheel may be used for the power source, and the motor output shaft of the eccentric wheel is not in the center, but at a certain position of the edge, the eccentric wheel may be specifically selected according to the maximum limit of the required azimuth adjustment, and the movable rack 52 may also be made to reciprocate left and right.

As shown in fig. 4, as a preferred embodiment of the present invention, the measuring assembly 6 includes: a side plate 61 connected to the steering mechanism 5; a threaded rod 62, both ends of which are rotatably connected to the side plates 61; a power member 63 connected to one end of the threaded rod 62; the thread block 64 is sleeved on the threaded rod 62 in a threaded manner and forms a screw pair rotation with the threaded rod 62; a measuring rod 65, one end of which is connected to the screw block 64; a measuring scale 66, both ends of which are connected to the measuring rod 65 and parallel to the measuring rod 65; a guide block 67 connected to the other end of the measuring rod 65; the guide rod 68 is fixed on the side plate 61 at both ends, and the guide block 67 is sleeved on the guide rod 68 and can slide on the guide rod 68.

In one embodiment of the invention, when the actual measurement is performed, the steering mechanism 5 aligns the head end of the building to be measured with the side plate 61, the power piece 63 is started, the power piece 63 can be a part capable of providing power by a motor or the like, the output shaft of the power piece 63 drives the threaded rod 62 to rotate, the threaded rod 62 rotates to drive the threaded block 64, the measuring rod 65 and the guide block 67 to move rightwards along the guide rod 68, when the measuring rod moves to the tail end of the building to be measured, the reading of the measuring ruler 66 can be read through the distance sensor, so that the measurement process is completed, and when the measuring is performed, the measuring can be performed for several times, so that the error is reduced.

In this embodiment, the measuring ruler 66 may be a plurality of components, for example, an angle ruler may be replaced by an angle ruler, or a tape measure may be replaced by a tape measure, so long as the measuring ruler can be rolled up after the measuring, and the actual measuring requirement can be met.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (5)

1. Super high-rise building engineering measuring equipment, characterized in that, super high-rise building engineering measuring equipment includes:

a bottom plate;

the lifting assembly is connected with the bottom plate and used for lifting the equipment to a set height;

the swing assembly is connected to the lifting assembly and is used for rotating in the horizontal direction to adjust the measuring direction; wherein, swing subassembly includes: the supporting groove is connected with the lifting assembly, and the steering mechanism is arranged in the supporting groove and is connected with the supporting groove;

the measuring assembly is connected with the swinging assembly and is used for accurately measuring the high-rise building;

the steering mechanism includes: the guide posts are arranged in the supporting grooves, the two ends of the guide posts are connected with the supporting grooves, and at least two guide posts are arranged;

the movable rack is sleeved on the guide post and can slide on the guide post;

a rotating gear meshed with the movable rack;

the shaft lever is sleeved on the rotating gear and fixedly connected with the rotating gear;

an elastic member fixed between the moving rack and the support groove;

the driving part is sleeved on the guide post and used for providing steering power for the shaft lever;

the driving part includes: the two ends of the mounting plate are connected with the guide posts;

a driving cam mounted on the mounting plate;

a roller in contact with the driving cam;

and the pressing block is connected with the roller rotating shaft through a connecting rod.

2. The super high rise building engineering measurement apparatus of claim 1, wherein the lifting assembly comprises:

the supporting seat is connected with the bottom plate through a supporting rod;

one end of the vertical rod is fixed on the supporting seat and is used for providing guidance for equipment in the process of lifting the equipment;

the top plate is connected with the other end of the vertical rod and used for limiting the rising height and blocking rainwater;

the power mechanism is connected to one side of the supporting seat, which is far away from the bottom plate, and is used for providing power support for the ascending process of the measuring assembly;

and the lifting mechanism is connected with the power mechanism and used for lifting to transport the measuring assembly to a set height.

3. The super high-rise building engineering measurement apparatus according to claim 2, wherein the power mechanism includes:

one end of the limiting rod is connected to the vertical rod;

the base is sleeved in the limit rotating rod and can slide on the limit rotating rod;

the driving piece is fixed on one side of the base and matched with the limiting rod, and is used for preventing the driving piece from rotating when working;

the sleeve joint piece is sleeved on the central shaft of the driving piece and can rotate on the central shaft of the driving piece;

the guide gear is fixed with one end of the central shaft of the driving piece;

and the guide rack is meshed with the guide gear and is fixed on the supporting seat and used for driving the lifting mechanism to move upwards.

4. The super high-rise building engineering measurement apparatus according to claim 2, wherein the lifting mechanism includes:

one end of the first sliding rod is connected with the vertical rod;

the first sliding piece is in sliding sleeve joint with the first sliding rod and can freely slide on the first sliding rod;

a first hinge lever having one end hinged with the first slider;

the lifting plate is hinged to the first hinging rod and provided with a groove, and is fixedly connected with the swinging assembly and used for lifting the swinging assembly and the measuring assembly to a proper height;

the second slide bar is connected with a groove formed in the lifting plate;

the second sliding piece is sleeved on the second sliding rod and can slide on the second sliding rod;

and the two ends of the second hinging rod are respectively hinged with the second sliding piece and the first hinging rod, and the second hinging rod is rotationally connected with the middle part of the first hinging rod.

5. The super high-rise building engineering measurement apparatus according to claim 1, wherein the measurement assembly includes:

the side plate is connected with the steering mechanism;

the two ends of the threaded rod are rotatably connected to the side plates;

the power piece is connected to one end of the threaded rod;

the thread block is sleeved on the threaded rod in a threaded manner and forms a screw pair with the threaded rod to rotate;

one end of the measuring rod is connected with the thread block;

the two ends of the measuring ruler are connected with the measuring rod and are parallel to the measuring rod;

the guide block is connected with the other end of the measuring rod;

the two ends of the guide rod are fixed on the side plates, and the guide block is sleeved on the guide rod and can slide on the guide rod.

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