CN215598426U - Vertical detection device for constructional engineering - Google Patents

Abstract

The utility model provides a building engineering vertical detection device which comprises a base, wherein a lifting mechanism is arranged on the base, an interval adjusting mechanism is arranged at the top of the lifting mechanism, and detection rulers which are vertically arranged are respectively arranged at two ends of the interval adjusting mechanism. The utility model has the following beneficial effects: the utility model not only can well vertically detect one wall body, but also can simultaneously vertically detect two wall bodies, the whole detection process is simple and quick to operate, the labor burden is reduced, and the detection working efficiency is improved.

Description

Vertical detection device for constructional engineering

Technical Field

The utility model relates to the technical field of perpendicularity detection devices, in particular to a perpendicularity detection device for building engineering.

Background

The building engineering is an engineering entity and the like of various technical works such as planning, surveying, designing, constructing, completing and the like for newly building, reconstructing or expanding building and auxiliary building facilities, and vertical detection is needed in the building engineering construction, so that a vertical detection ruler is used.

The existing vertical detection ruler is generally operated manually by workers in the use process, so that the operation is troublesome, the higher part of a wall body cannot be detected, only partial detection can be carried out on the wall body, and the detection result has no strong persuasion; and the existing vertical detection ruler can only detect one wall, and can not detect two walls simultaneously, thereby reducing the working efficiency of detection.

SUMMERY OF THE UTILITY MODEL

The utility model provides a building engineering verticality detection device, which solves the problem of low wall surface verticality detection efficiency in the prior art.

The technical scheme of the utility model is realized as follows:

the utility model provides a building engineering vertical detection device, includes the base, is equipped with elevating system on the base, and the elevating system top is equipped with interval adjustment mechanism, and interval adjustment mechanism's both ends are equipped with the vertical detection chi of arranging respectively, and elevating system makes the detection chi can measure the not wall body straightness that hangs down of co-altitude, and interval adjustment mechanism's both ends all are equipped with the detection chi, make detection device can measure two-sided wall body simultaneously.

Elevating system includes two at least symmetrical arrangement's sleeve and actuating mechanism I, and the sleeve is connected with base sliding fit, and actuating mechanism I drives the sleeve and keeps away from each other or be close to, actuating mechanism I fixed set up on the base and with muffjoint, the activity is equipped with the bracing piece on the sleeve, the upper end of bracing piece is articulated with interval adjustment mechanism, actuating mechanism I drives each sleeve and moves in opposite directions or opposite directions, changes the inclination of bracing piece, and then makes interval adjustment mechanism rise or descend.

The lower part of the sleeve is provided with a limiting rod, the base is provided with a limiting groove, and the limiting groove is connected with the limiting rod in a sliding fit mode.

When actuating mechanism I was biax servo motor, telescopic quantity was two, was equipped with symmetrical arrangement's first threaded rod and second threaded rod on the biax servo motor, and the screw thread opposite direction of first threaded rod and second threaded rod, two sleeves respectively with first threaded rod and second threaded rod screw-thread fit connection, biax servo motor drives first threaded rod and second threaded rod syntropy and rotates, and then makes two sleeves or opposite movement in opposite directions.

The interval adjustment mechanism comprises an operation box, two movable columns and a driving mechanism II for driving the movable columns to slide are arranged in the operation box in a sliding mode, the end portions of the movable columns stretch out of the two ends of the operation box, the detection ruler is fixedly arranged at the end portions of the movable columns, the driving mechanism II drives the movable columns to move, and the movable columns are controlled to stretch out of the length of the operation box.

The two movable columns are provided with sliding blocks, the inner wall of the operation box is provided with a sliding groove, and the sliding blocks are connected with the sliding groove in a sliding fit mode.

The driving mechanism II comprises a single-shaft servo motor, the single-shaft servo motor is fixedly arranged on the operation box, a gear is arranged on an output shaft of the single-shaft servo motor, a rack is arranged on the movable column, the two movable columns are respectively located on the upper side and the lower side of the gear, the gear is connected with the rack in a matched mode, the gear rotates to enable the rack to drive the two movable columns to move in opposite directions, and then the movable columns stretch out or retract.

The bottom of the operation box is fixedly provided with a connecting block, and the connecting block is movably hinged with the upper end of the supporting rod.

The fixed handle that pushes away that is equipped with on the base pushes away and installs first switch and the second switch of falling in the same direction as the switch, first switch and unipolar servo motor electric connection, second switch and biax servo motor electric connection in the same direction as.

At least 3 universal wheels with brakes are arranged on the lower surface of the base, and the universal wheels facilitate the movement of the vertical detection device.

The utility model has the following beneficial effects:

1. the vertical detection device not only can well perform vertical detection on one wall body, but also can perform vertical detection on two wall bodies simultaneously, and the whole detection process is simple and quick to operate, reduces the labor burden and improves the working efficiency of detection;

2. the lifting mechanism is arranged, the first threaded rod and the second threaded rod are driven to rotate simultaneously through the double-shaft servo motor, and due to the fact that the thread directions of the first threaded rod and the second threaded rod are opposite, the sleeves are close to each other under the limiting of the limiting rod and the limiting groove, the inclination angle of the supporting rod is changed, and finally the operation box can drive the two detection rulers to gradually ascend and can detect different parts of a wall body, so that the detection result has strong persuasion;

3. be provided with interval adjustment mechanism, rotate through unipolar servo motor drive gear for two racks with it meshing drive two movable posts and keep away from each other, and final two are detected the chi and are kept away from each other, thereby realize interval adjustment, when carrying out perpendicular detection to two wall bodies like this, can adapt the longer two wall bodies of interval, and then reduced the limitation in the use.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural view of a vertical detection device for construction engineering.

Fig. 2 is a sectional view of the operation box.

Fig. 3 is a schematic structural view of the base and the push handle.

In the figure: 1-base, 2-operation box, 3-connecting block, 4-double-shaft servo motor, 5-first threaded rod, 6-second threaded rod, 7-sleeve, 8-supporting rod, 9-limiting groove, 10-limiting rod, 11-single-shaft servo motor, 12-gear, 13-rack, 14-movable column, 15-detection ruler, 16-supporting block, 17-sliding groove, 18-sliding block, 19-movable hole, 20-push handle, 21-first reversing switch and 22-second reversing switch.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without inventive effort based on the embodiments of the present invention, are within the scope of the present invention.

Embodiment 1, as shown in fig. 1, a vertical detection device for construction engineering includes a base 1, wherein at least 3 universal wheels with brakes are provided on a lower surface of the base 1, specifically, the number of the universal wheels is 4, and the universal wheels are uniformly arranged on the lower surface of the base 1, so that the vertical detection device can be conveniently moved and fixed; be equipped with elevating system on the base 1, the elevating system top is equipped with interval adjustment mechanism, and interval adjustment mechanism's both ends are equipped with the vertical detection ruler 15 of arranging respectively, and the adjustable interval adjustment mechanism's of elevating system height, and then make the straightness that hangs down that detection ruler 15 can detect the not co-altitude wall body, and the adjustable interval of two detection rulers 15 of interval adjustment mechanism makes detection device can detect two wall bodies simultaneously.

Further, the lifting mechanism comprises at least two sleeves 7 and a driving mechanism I which are symmetrically arranged, the driving mechanism I can be a hydraulic cylinder or a motor, the sleeves 7 are connected with the base 1 in a sliding fit manner, a limiting rod 10 is arranged at the lower part of each sleeve 7, a limiting groove 9 is arranged on the base 1, the limiting groove 9 is connected with the limiting rod 10 in a sliding fit manner, the sleeves 7 move along the direction of the limiting groove 9, the driving mechanism I drives the sleeves 7 to mutually move away from or approach to each other, the driving mechanism I is fixedly arranged on the base 1 and connected with the sleeves 7, a supporting rod 8 is hinged on each sleeve 7, the upper end of each supporting rod 8 is hinged with the interval adjusting mechanism, the driving mechanism I drives the sleeves 7 to move along the direction of the limiting grooves 9, the relative intervals between the sleeves 7 are changed, the inclination angle of the supporting rod 8 can be changed by changing the position of each sleeve 7, and the height of the interval adjusting mechanism which is supported at the upper end of the supporting rod 8 is changed, finally, the height of the detection ruler 15 is changed, and the detection of the verticality of the wall bodies with different heights by the vertical detection device is realized.

Embodiment 2, when actuating mechanism I was biax servo motor 4, the quantity of sleeve 7 is two, be equipped with symmetrical arrangement's first threaded rod 5 and second threaded rod 6 on the biax servo motor 4, biax servo motor 4 can drive first threaded rod 5 and the synchronous rotation of second threaded rod 6, and the screw direction of first threaded rod 5 and second threaded rod 6 is opposite, two sleeve 7 respectively with first threaded rod 5 and the 6 screw-thread fit connection of second threaded rod, when first threaded rod 5 and the 6 synchronous rotations of second threaded rod, two sleeve 7 move or opposite movement, change the relative distance between the sleeve 7.

Further, be equipped with two supporting shoes 16 on the base 1, two supporting shoes 16 rotate with the tip of first threaded rod 5 and second threaded rod 6 respectively and are connected, and supporting shoe 16 provides the support for the tip of first threaded rod 5 and second threaded rod 6, guarantees the steady when first threaded rod 5 and second threaded rod 6 rotate, and then guarantees actuating mechanism I's stable in structure.

The other structure is the same as that of embodiment 1.

Embodiment 3, interval adjustment mechanism includes control box 2, the fixed connecting block 3 that is equipped with in 2 bottoms of control box, connecting block 3 is articulated with the upper end activity of bracing piece 8, it has two movable posts 14 and drives the gliding actuating mechanism II of movable post 14 to slide in the control box 2, the both ends of control box 2 are stretched out to the tip of movable post 14, the fixed tip that sets up at movable post 14 of measuring tape 15, actuating mechanism II drives movable post 14 motion, and then change the relative interval of checking tape 15, make perpendicular detection device be applicable to the straightness detection that hangs down of the two-sided wall body of different intervals.

Further, as shown in fig. 2, the two movable columns 14 are both provided with a sliding block 18, the inner wall of the operation box 2 is provided with a sliding groove 17, the sliding block 18 is connected with the sliding groove 17 in a sliding fit manner, and the sliding groove 17 limits the moving direction of the sliding block 18, so as to limit the moving direction of the movable columns 14. Actuating mechanism II includes unipolar servo motor 11, unipolar servo motor 11 is fixed to be set up on control box 2, unipolar servo motor 11's main shaft stretches into inside control box 2, and be equipped with gear 12 on unipolar servo motor 11's the output shaft, be equipped with rack 13 on the activity post 14, and two activity posts 14 are located gear 12's upper and lower both sides respectively, gear 12 and rack 13 cooperation are connected, gear 12 rotates and to drive rack 13 and remove, and then make activity post 14 slide along the direction of spout 17, change the tip interval of two activity posts 14, and then change two relative spacing that detect chi 15.

Further, as shown in fig. 3, fixed being equipped with push handle 20 on the base 1, push handle 20 is convenient for operating personnel to promote perpendicular detection device and removes, install first two direction switch 21 and second two direction switch 22 on push handle 20 in proper order, first two direction switch 21 and unipolar servo motor 11 electric connection, second two direction switch 22 and 4 electric connection of biax servo motor, first two direction switch 21 and second two direction switch 22 are installed on push handle 20, make things convenient for the staff to operate, start-stop and positive and negative dress of first two direction switch 21 control unipolar servo motor 11, start-stop and positive and negative dress of second two direction switch 22 control biax servo motor 4.

The other structure is the same as that of embodiment 1 or embodiment 2.

The vertical detection device has the working principle that: before the operation box 2 is used at the lowest position, when two walls are vertically detected, the whole vertical detection device is moved between the two walls, firstly, the forward switch of the first forward and backward switch 21 is started according to actual conditions to enable the single-shaft servo motor 11 to drive the gear 12 to rotate forwards, so that the two racks 13 meshed with the gear 12 drive the two movable columns 14 to be away from each other, and finally, the two detection rulers 15 are away from each other, thereby realizing distance adjustment, so that the two walls with longer distance can be adapted, and further, the limitation in the use process is reduced, after the adjustment is finished, the forward switch of the second forward and backward switch 22 is started to enable the double-shaft servo motor 4 to drive the first threaded rod 5 and the second threaded rod 6 to rotate forwards simultaneously, because the thread directions of the first threaded rod 5 and the second threaded rod 6 are opposite, then under the limit of the two limit rods 10 and the two limit grooves 9, the two sleeves 7 on the first threaded rod 5 and the second threaded rod 6 are close to each other, under the articulated effect of bracing piece 8 that two slopes set up, make control box 2 rise, and then make control box 2 drive two measuring rulers 15 and rise, detect from bottom to top like this, can detect the different positions of wall body to make the testing result possess stronger persuasion.

After detecting the completion, all open the down switch of first down and forward switch 21 and second down and forward switch 22, two sleeves 7 keep away from each other and finally drive control box 2 and descend to the minimum this moment, and two detection chi 15 are close to each other and get back to the normal position, conveniently remove through the universal wheel that sets up, and can die the universal wheel lock after removing the completion and fix, install on pushing away handle 20 through first down and forward switch 21 and second down and forward switch 22, make things convenient for the staff to operate, and when examining a face wall body, can dismantle one detection chi 15, and need not start unipolar servo motor 11.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (10)

1. The utility model provides a vertical detection device of building engineering, includes base (1), its characterized in that is equipped with elevating system on base (1), and the elevating system top is equipped with interval adjustment mechanism, and interval adjustment mechanism's both ends are equipped with vertical detection chi (15) of arranging respectively.

2. The building engineering vertical detection device according to claim 1, wherein the lifting mechanism comprises at least two symmetrically arranged sleeves (7) and a driving mechanism I, the sleeves (7) are connected with the base (1) in a sliding fit manner, the driving mechanism I drives the sleeves (7) to be away from or close to each other, the driving mechanism I is fixedly arranged on the base (1) and connected with the sleeves (7), supporting rods (8) are movably arranged on the sleeves (7), and the upper ends of the supporting rods (8) are hinged to the interval adjusting mechanism.

3. The building engineering vertical detection device according to claim 2, wherein a limiting rod (10) is arranged at the lower part of the sleeve (7), a limiting groove (9) is arranged on the base (1), and the limiting groove (9) is connected with the limiting rod (10) in a sliding fit manner.

4. The vertical detection device for the building engineering as claimed in claim 3, wherein when the driving mechanism I is a double-shaft servo motor (4), the number of the sleeves (7) is two, the double-shaft servo motor (4) is provided with a first threaded rod (5) and a second threaded rod (6) which are symmetrically arranged, the thread directions of the first threaded rod (5) and the second threaded rod (6) are opposite, and the two sleeves (7) are respectively in thread fit connection with the first threaded rod (5) and the second threaded rod (6).

5. The building engineering vertical detection device according to any one of claims 1 to 4, characterized in that the spacing adjustment mechanism comprises an operation box (2), two movable columns (14) and a driving mechanism II for driving the movable columns (14) to slide are slidably arranged in the operation box (2), the end parts of the movable columns (14) extend out of the two ends of the operation box (2), and the detection ruler (15) is fixedly arranged at the end parts of the movable columns (14).

6. The building engineering vertical detection device according to claim 5, characterized in that the two movable columns (14) are respectively provided with a sliding block (18), the inner wall of the operation box (2) is provided with a sliding groove (17), and the sliding blocks (18) are connected with the sliding grooves (17) in a sliding fit manner.

7. The building engineering vertical detection device according to claim 6, wherein the driving mechanism II comprises a single-shaft servo motor (11), the single-shaft servo motor (11) is fixedly arranged on the operation box (2), a gear (12) is arranged on an output shaft of the single-shaft servo motor (11), a rack (13) is arranged on the movable column (14), the two movable columns (14) are respectively positioned on the upper side and the lower side of the gear (12), and the gear (12) and the rack (13) are connected in a matching manner.

8. The construction engineering vertical detection device according to claim 7, wherein the bottom of the operation box (2) is fixedly provided with a connecting block (3), and the connecting block (3) is movably hinged with the upper end of the support rod (8).

9. The vertical detection device for the building engineering according to claim 7 or 8, characterized in that a push handle (20) is fixedly arranged on the base (1), a first reversing switch (21) and a second reversing switch (22) are sequentially arranged on the push handle (20), the first reversing switch (21) is electrically connected with the single-shaft servo motor (11), and the second reversing switch (22) is electrically connected with the double-shaft servo motor (4).

10. The building engineering vertical detection device according to any one of claims 1 to 4 and 6 to 8, wherein at least 3 universal wheels with brakes are arranged on the lower surface of the base (1).

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