CN220490041U - Integrated measuring device for construction engineering construction elevation transfer - Google Patents

Abstract

The utility model relates to the technical field of measuring device structures, in particular to an integrated measuring device for the elevation transfer of building engineering construction, which comprises a control box, a lifting component and a rotary adjusting component, wherein a control cavity is arranged in the control box, the lifting component is arranged in the control cavity, the lifting component comprises a scale guide plate and a supporting spring, a measuring instrument housing is arranged at the upper end of the supporting spring, the scale guide plate vertically penetrates through the lower end of the control box, the control box is arranged at the lower end of a supporting leg mounting plate, when the ground is uneven, a fixed foot at the outer side of the lower end of the supporting leg mounting plate is adjusted, so that the instrument achieves the required basic balance and height, the self-leveling device in the instrument is matched, the self-leveling device can slightly level, and when the instrument is positioned before measurement, a horizontal laser emitting port and a wire are rapidly corresponding through the lifting component and the rotary adjusting component arranged in the control box, the geometrical position and the height of the instrument are prevented from being repeatedly adjusted, and the measuring efficiency is improved.

Description

Integrated measuring device for construction engineering construction elevation transfer

Technical Field

The utility model relates to the technical field of measuring device structures, in particular to an integrated measuring device for building engineering construction elevation transfer.

Background

In the construction measurement of building engineering, the vertical transmission of the construction elevation is an important work in daily construction measurement, and the construction elevation penetrates through each stage of construction of the construction project to provide an accurate elevation reference for site construction;

at present, the common method for vertically transferring the construction elevation of the building engineering comprises a total station overhead distance measuring method, and the total station overhead distance can be used for transferring the elevation in a long distance through electronic distance measurement, so that the measuring precision is high;

however, the geometric center position and the instrument height of the total station need steel ruler measurement, and large errors are easy to occur.

Disclosure of Invention

The utility model aims to provide an integrated measuring device for construction elevation transmission of building engineering, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: an integrated measuring device for building engineering construction elevation transfer, the measuring device structure comprising:

the control box is internally provided with a control cavity;

the lifting assembly is arranged in the control cavity and comprises a scale guide plate and a supporting spring, the upper end of the supporting spring is provided with a measuring instrument housing, and the scale guide plate vertically penetrates through the lower end of the control box;

the rotary adjusting assembly comprises an adjusting gear and a rotary table, the adjusting gear is located at the lower end in the control cavity, and the rotary table is located at one side outside the control box.

Preferably, the control box upper end is provided with the landing leg mounting panel, and circular slot has been seted up at landing leg mounting panel center, and the supporting spring upper end runs through circular slot setting, and the scale baffle is vertical to be located supporting spring lower extreme center.

Preferably, the scale guide plate is vertically arranged at the center of the lower end of the supporting spring, a groove is formed in one side of the scale guide plate, and a plurality of adjusting teeth are symmetrically arranged in the groove.

Preferably, the adjusting gear is arranged close to one side of the groove of the scale guide plate, and one side tooth of the adjusting gear is meshed with one side tooth of the scale guide plate.

Preferably, a supporting table is horizontally arranged on one side of the control box, one side of the supporting table penetrates through the control box, a synchronizing shaft is horizontally arranged in the center of one side of the adjusting gear, one side of the synchronizing shaft horizontally penetrates through the supporting table, and the turntable is vertically arranged on one side of the synchronizing shaft penetrating through the supporting table.

Preferably, the supporting table is arranged at the lower end of one side outside the control box and is provided with a spring groove, a guide rod is vertically arranged in the spring groove, a movable block is movably sleeved at the upper end of the spring groove, a supporting spring is sleeved at the lower end of the spring groove, the upper end of the supporting spring is in contact with the lower end of the movable block, one side of the movable block is horizontally provided with a limiting rod, one side of the spring groove penetrates through the supporting table and is close to one side of the turntable and is provided with a strip-shaped groove, and the limiting rod horizontally penetrates through the insertion strip-shaped groove.

Preferably, a plurality of clamping grooves are symmetrically formed in the peripheral side of the rotary table, and one side of the limiting rod penetrating through the strip-shaped groove is horizontally inserted into one side of the clamping groove.

Preferably, four control buttons are symmetrically arranged at the upper end of the measuring instrument housing, a vertical laser emission port is vertically arranged at the center of the upper end of the measuring instrument housing, a horizontal laser emission port is horizontally arranged on one side of the measuring instrument housing, a building wall body is vertically arranged on one side of the measuring instrument housing, a wire is horizontally arranged on one side of the building wall body, a building floor is horizontally arranged above the measuring instrument housing, a marking hole is formed in the building floor and is positioned right above the measuring instrument housing, a comparison target plate is horizontally arranged above the marking hole, the horizontal laser emission port is correspondingly arranged with the wire, and the vertical laser emission port is correspondingly arranged with the comparison target plate.

Compared with the prior art, the utility model has the beneficial effects that:

through setting up the control box at landing leg mounting panel lower extreme, when the ground is uneven, adjust the fixed foot in landing leg mounting panel lower extreme outside, make the instrument reach required basic balance and height, the self-leveling device of taking in the cooperation instrument, but self slight leveling, when the instrument is measured the preceding location, make horizontal laser emission mouth correspond fast with a line through the lifting unit and the rotatory adjusting part that control box inside set up, avoid carrying out the repeated adjustment to the geometric position and the height of instrument, reach the purpose that improves measurement efficiency.

Drawings

FIG. 1 is a schematic diagram of the measurement state structure of the device of the present utility model;

FIG. 2 is a schematic diagram of the leg mounting plate connection structure of the present utility model;

FIG. 3 is a schematic view of the top structure of the meter housing of the present utility model;

FIG. 4 is a schematic diagram of a partial side cut structure of the control box of the present utility model;

FIG. 5 is a schematic view of a movable block connection structure according to the present utility model;

fig. 6 is a schematic view of a connecting structure of a stop lever according to the present utility model.

In the figure: the measuring instrument comprises a measuring instrument housing 1, a supporting leg mounting plate 2, a control box 3, a scale guide plate 4, a limit rod 6, a spring groove 7, a rotary table 8, an adjusting gear 10, a synchronous shaft 11, a supporting table 12, a control cavity 13, a supporting spring 14, a guide rod 15, a meter line 16, a horizontal laser emission port 17, a vertical laser emission port 18, a comparison target plate 19 and a control button 21.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-6, the present application provides the following three preferred embodiments.

Example 1

The utility model provides a building engineering construction elevation transmission integrated measuring device, including control box 3, be equipped with control chamber 13 in the control box 3, lifting unit arranges in control chamber 13, lifting unit includes scale baffle 4 and supporting spring 14, the supporting spring 14 upper end is equipped with measuring apparatu housing 1, scale baffle 4 vertically runs through control box 3 lower extreme, the control box 3 upper end is provided with landing leg mounting panel 2, circular slot has been seted up at landing leg mounting panel 2 center, the setting of circular slot is run through to supporting spring 14 upper end, scale baffle 4 vertically locates at supporting spring 14 lower extreme center, the recess has been seted up to one side of scale baffle 4, the symmetry is equipped with a plurality of regulation tooth in the recess, scale baffle 4 is prismatic plate structure setting, when measuring apparatu housing 1 carries out the upper and lower activity in control box 3 through landing leg mounting panel 2, it is stabilized to it, and one side of scale baffle 4 is equipped with the scale mark;

the lower end of the supporting leg mounting plate 2 is symmetrically provided with a plurality of telescopic supporting legs which are common in the prior art, so that the supporting leg mounting plate 2 and the measuring instrument housing 1 can be kept basically horizontally, and the use of the ground-free condition is adapted;

in addition, the upper end of the supporting leg mounting plate 2 can be provided with a horizontal bubble, so that the horizontal postures of the measuring instrument housing 1 and the supporting leg mounting plate 2 can be conveniently observed;

the instrument in the instrument housing 1 is self-contained with the leveling system of the prior art, and after the leg mounting plate 2 and the instrument housing 1 are substantially level, a more precise level fine adjustment is possible.

Example two

On the basis of the first embodiment, the height positions of the scale guide plate 4 and the measuring instrument housing 1 are adjusted in an up-down movable mode, the rotary adjusting assembly comprises an adjusting gear 10 and a rotary table 8, the adjusting gear 10 is located at the inner lower end of a control cavity 13, the rotary table 8 is located at one side outside the control box 3, the adjusting gear 10 is arranged at one side close to a groove of the scale guide plate 4, teeth on one side of the adjusting gear 10 are meshed with teeth on one side of the scale guide plate 4, a supporting table 12 is horizontally arranged at one side of the control box 3, one side of the supporting table 12 penetrates through the control box 3, a synchronizing shaft 11 is horizontally arranged at one side of the synchronizing shaft 11 and horizontally penetrates through the supporting table 12, the rotary table 8 is vertically arranged at one side of the synchronizing shaft 11 penetrating through the supporting table 12, a spring groove 7 is formed in the lower end of one side of the supporting table 12, a guide rod 15 is vertically arranged in the spring groove 7, a movable block is sleeved at the upper end of the spring groove 7, a supporting spring 14 is sleeved with a supporting spring 14, one side of the movable block is horizontally provided with a limiting rod 6, one side of the movable block is connected with one side of the supporting spring 7, one side of the supporting table 12 penetrates through the supporting table 8 and is arranged at one side of the opposite side of the rotary table 8, which penetrates through the horizontal slot 6, and is symmetrically arranged at one side of the clamping rod 6;

the rotation of the synchronizing shaft 11 is controlled through the rotary disc 8, the rotation of the adjusting gear 10 is achieved, the adjusting gear 10 pushes the scale guide plate 4 downwards or upwards through teeth, the height change of the measuring instrument housing 1 is completed, the horizontal laser emission port 17 corresponds to the one meter line 16 horizontally, then the vertical laser emission port 18 corresponds to the contrast target plate 19 vertically, and then the measuring data is read through the data display screen of the measuring instrument housing 1, so that the measuring instrument is simple in operation and convenient to use.

Example III

On the basis of the second embodiment, four control buttons 21 are symmetrically arranged at the upper end of the measuring instrument housing 1, a vertical laser emission port 18 is vertically arranged in the center of the upper end of the measuring instrument housing 1, a horizontal laser emission port 17 is horizontally arranged at one side of the measuring instrument housing 1, a building wall body is vertically arranged at one side of the building wall body, a wire 16 is horizontally arranged at one side of the building wall body, a building floor is horizontally arranged above the measuring instrument housing 1, a marking hole is formed right above the measuring instrument housing 1, a comparison target plate 19 is horizontally arranged above the marking hole by the damping floor, the horizontal laser emission port 17 is correspondingly arranged with the wire 16, and the vertical laser emission port 18 is correspondingly arranged with the comparison target plate 19;

after the vertical laser emission port 18 corresponds to the contrast target plate 19, the light emitted from the horizontal laser emission port 17 can assist the building wall to draw a meter line 16;

the horizontal laser emission port 17 corresponds to the one-meter wire 16, so that the position of the measuring instrument housing 1 can be rapidly approved, the measuring efficiency and accuracy are improved, the operation is simple, and the use is convenient.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a building engineering construction elevation transmission integrated form measuring device which characterized in that: the measuring device includes:

the control box (3), the said control box (3) has control chambers (13);

the lifting assembly is arranged in the control cavity (13) and comprises a scale guide plate (4) and a supporting spring (14), the upper end of the supporting spring (14) is provided with a measuring instrument housing (1), and the scale guide plate (4) vertically penetrates through the lower end of the control box (3);

the rotary adjusting assembly comprises an adjusting gear (10) and a rotary table (8), the adjusting gear (10) is located at the inner lower end of the control cavity (13), and the rotary table (8) is located at one side outside the control box (3).

2. The integrated measurement device for building engineering construction elevation transfer according to claim 1, wherein: the control box (3) upper end is provided with landing leg mounting panel (2), and circular slot has been seted up at landing leg mounting panel (2) center, and the setting of circular slot is run through to supporting spring (14) upper end, and scale baffle (4) are vertical to be located supporting spring (14) lower extreme center.

3. The integrated measurement device for building engineering construction elevation transfer according to claim 2, wherein: the scale guide plate (4) is vertically arranged at the center of the lower end of the supporting spring (14), a groove is formed in one side of the scale guide plate (4), and a plurality of adjusting teeth are symmetrically arranged in the groove.

4. A construction engineering construction elevation transfer integrated measuring apparatus according to claim 3, wherein: the adjusting gear (10) is arranged close to one side of the groove of the scale guide plate (4), and one side tooth of the adjusting gear (10) is meshed and connected with one side tooth of the scale guide plate (4).

5. The integrated measurement device for building engineering construction elevation transfer according to claim 4, wherein: one side level of control box (3) is equipped with supporting bench (12), and one side of supporting bench (12) runs through control box (3) setting, and one side center level of adjusting gear (10) is equipped with synchronizing shaft (11), and synchronizing shaft (11) one side level runs through supporting bench (12) setting, and one side of supporting bench (12) is run through to synchronizing shaft (11) is located vertically to carousel (8).

6. The integrated measurement device for building engineering construction elevation transfer according to claim 5, wherein: the supporting table (12) is arranged at the lower end of one side outside the control box (3), a spring groove (7) is formed in the lower end of one side, a guide rod (15) is vertically arranged in the spring groove (7), a movable block is movably sleeved at the upper end of the spring groove (7), a supporting spring (14) is sleeved at the lower end of the spring groove (7), the upper end of the supporting spring (14) is in contact with the lower end of the movable block, a limit rod (6) is horizontally arranged at one side of the movable block, one side in the spring groove (7) penetrates through the supporting table (12) and is close to one side of the turntable (8), a strip-shaped groove is formed, and the limit rod (6) horizontally penetrates through the insertion strip-shaped groove.

7. The integrated measurement device for building engineering construction elevation transfer according to claim 6, wherein: a plurality of clamping grooves are symmetrically formed in the peripheral side of the rotary disc (8), and a limiting rod (6) penetrates through one side of the strip-shaped groove and is horizontally inserted into one side of the clamping groove.

8. The integrated measurement device for building engineering construction elevation transfer according to claim 7, wherein: four control buttons (21) are symmetrically arranged at the upper end of the measuring instrument housing (1), a vertical laser emission opening (18) is vertically arranged in the center of the upper end of the measuring instrument housing (1), a horizontal laser emission opening (17) is horizontally arranged on one side of the measuring instrument housing (1), a building wall is vertically arranged on one side of the measuring instrument housing (1), a wire (16) is horizontally arranged on one side of the building wall, a building floor is horizontally arranged above the measuring instrument housing (1), a marking hole is formed in the building floor right above the measuring instrument housing (1), a comparison target plate (19) is horizontally arranged above the marking hole, the horizontal laser emission opening (17) and the wire (16) are correspondingly arranged, and the vertical laser emission opening (18) and the comparison target plate (19) are correspondingly arranged.