CN220930602U - Anemograph for bridge construction monitoring - Google Patents

Abstract

The utility model discloses an anemograph for bridge construction monitoring, which comprises a base, wherein moving wheels are uniformly arranged below the base, a central positioning mechanism and an auxiliary inserting and fixing assembly are arranged on the base, a supporting column is arranged at the center of the base, the top end of the supporting column is hinged with a supporting plate, a supporting column is arranged on the supporting plate, a wind direction sensing element and a wind speed sensing element are rotatably sleeved on the supporting column, the wind speed sensing element is positioned above the wind direction sensing element, and a levelness adjusting mechanism is arranged at the joint of the supporting plate and the supporting column. The utility model belongs to the technical field of bridge construction monitoring, and particularly relates to an anemoscope which can level a plane supporting the anemoscope, is convenient for stable placement, avoids strong wind from blowing down, and is convenient for pushing and moving for bridge construction monitoring.

Description

Anemograph for bridge construction monitoring

Technical Field

The utility model belongs to the technical field of bridge construction monitoring, and particularly relates to an anemoscope for bridge construction monitoring.

Background

The anemoclinograph is widely applied, can provide accurate meteorological data, can also provide relevant reference data such as wind speed and the like, is favorable for data personnel to develop work and operation, and can provide important basis for project engineering in the bridge construction field.

In bridge construction, the place of construction is close to the waters more, and soil is more moist, and the anemoscope can't be fixed, when wind-force is great, the phenomenon of toppling and collapsing still appears easily, is unfavorable for the long-term use of anemoscope, still can cause the instrument to damage and bring economic loss when serious, and is inconvenient for the operator to remove the place of anemoscope when using, also can not detect whether the mounting plane of anemoscope is level for easily causing the influence to the detection of wind direction because of placing the slope. Therefore, an anemoscope for bridge construction monitoring is provided, and the anemoscope is used for solving the technical problem.

Disclosure of utility model

In order to solve the problems, the utility model provides the anemoscope which can adjust the level of the plane supporting the anemoscope, is convenient for stable placement, avoids strong wind from blowing down, and is convenient for pushing and moving for bridge construction monitoring.

In order to realize the functions, the technical scheme adopted by the utility model is as follows: the utility model provides an anemograph for bridge construction monitoring, includes the base, evenly install under the base and remove the wheel, be provided with centering mechanism and supplementary plug-in module on the base, be provided with the support column on the center department of base, the top of support column articulates there is the backup pad, be provided with the pillar in the backup pad, rotatable sleeve joint wind direction sensing element and wind speed sensing element on the pillar, wind speed sensing element is located wind direction sensing element's top, the junction of backup pad and supporting column is provided with levelness adjustment mechanism.

As a preferable technical scheme of the utility model, the levelness adjusting mechanism comprises a driving motor, a wire winding roller and a pull rope, wherein connecting rings are arranged below two ends of the bottom wall of the supporting plate, the driving motor is provided with two groups and arranged on two sides of the supporting column, the wire winding roller is provided with two groups and respectively connected with the output ends of the driving motor, one end of the pull rope is connected with the connecting rings, and the other end of the pull rope is wound on the wire winding roller.

As a preferable technical scheme of the utility model, the central positioning mechanism comprises an electric push rod and a positioning nail, wherein the bottom ends of the base and the support column are respectively provided with a cavity and are mutually communicated, the electric push rod is arranged in the cavity, the positioning nail is arranged in the cavity and is connected with the bottom end of the electric push rod, and the bottom end of the positioning nail is movably arranged through the cavity and the bottom wall of the base.

As a preferable technical scheme of the utility model, the auxiliary inserting and fixing assembly comprises two groups of inserting ground nails and a hand wheel, wherein the inserting ground nails are respectively arranged at two ends of the base in a threaded rotation manner, and the hand wheel is arranged at the top end of the inserting ground nails.

As a preferable embodiment of the present utility model, the moving wheels are provided in four groups.

As a preferable technical scheme of the utility model, the driving motor is a servo motor.

The utility model adopts the structure to obtain the beneficial effects as follows: according to the anemoscope for bridge construction monitoring, through the arrangement of the levelness adjusting mechanism, the driving motor rotates to drive the pull rope on the winding roller to wind or unwind, the pull rope on one side is wound and the pull rope on the other side is correspondingly unwound, so that the supporting plate can rotate by taking the hinged position of the supporting plate and the supporting column as a rotation center, the plane for supporting the anemoscope can be adjusted to be horizontal, the influence on detection of wind direction due to inclination is prevented, the auxiliary inserting and fixing assembly and the central positioning mechanism are utilized, the ground inserting nails and the positioning nails are inserted into soil, stable placement is facilitated, equipment cannot collapse when wind power is large, and meanwhile, the movable wheels are utilized to conveniently push.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an anemoscope for bridge construction monitoring according to the present utility model;

Fig. 2 is a partial enlarged view of fig. 1 at a.

Wherein, 1, a base, 2, a movable wheel, 3, a center positioning mechanism, 4, an auxiliary inserting and fixing component, 5, a support column, 6, a support plate, 7, a support column, 8, a wind direction sensing element, 9 and a wind speed sensing element, 10, levelness adjustment mechanism, 11, driving motor, 12, take-up roller, 13, stay cord, 14, go-between, 15, electric putter, 16, locating nail, 17, cavity, 18, insert ground nail, 19, hand wheel.

Detailed Description

The following description of the embodiments of the present utility model will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the utility model are shown. 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.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. The present utility model will be described in further detail with reference to the accompanying drawings.

As shown in figures 1-2, the anemoscope for bridge construction monitoring comprises a base 1, wherein moving wheels 2 are uniformly arranged below the base 1, the moving wheels 2 are provided with four groups, pushing and monitoring are facilitated, a center positioning mechanism 3 and an auxiliary inserting and fixing assembly 4 are arranged on the base 1, the device can be stably placed, strong wind is prevented from blowing down, a support column 5 is arranged at the center of the base 1, the top end of the support column 5 is hinged with a support plate 6, a support column 7 is arranged on the support plate 6, a wind direction sensing element 8 and a wind speed sensing element 9 are rotatably sleeved on the support column 7, the wind speed sensing element 9 is positioned above the wind direction sensing element 8, and a levelness adjusting mechanism 10 is arranged at the joint of the support plate 6 and the support column 5, so that the plane supporting the wind direction sensing element 8 and the wind speed sensing element 9 can be adjusted to enable the detection result to be more accurate.

Levelness adjustment mechanism 10 includes driving motor 11, take-up roller 12 and stay cord 13, all be provided with go-between 14 under the diapire both ends of backup pad 6, driving motor 11 is servo motor, driving motor 11 sets up two sets of and locates the both sides of support column 5, take-up roller 12 sets up two sets of and connects respectively in driving motor 11's output, the one end of stay cord 13 is connected in go-between 14, the other end winding of stay cord 13 is on take-up roller 12, driving motor 11 rotates and drives stay cord 13 rolling or unreeling on the take-up roller 12, the corresponding unreeling of one side stay cord 13 rolling opposite side stay cord 13 can make backup pad 6 rotate with its articulated department with support column 5 as center of rotation, thereby leveling backup pad 6.

The center positioning mechanism 3 comprises an electric push rod 15 and a positioning nail 16, wherein the bottom ends of the base 1 and the support column 5 are respectively provided with a cavity 17 and are mutually communicated, the electric push rod 15 is installed in the cavity 17, the positioning nail 16 is arranged in the cavity 17 and is connected to the bottom end of the electric push rod 15, the bottom end of the positioning nail 16 is movably arranged through the cavity 17 and the bottom wall of the base 1, and after the device is pushed to move a monitoring position, the electric push rod 15 pushes the positioning nail 16, so that the positioning nail 16 is inserted into the ground for positioning; the auxiliary inserting and fixing assembly 4 comprises an inserting ground nail 18 and a hand wheel 19, wherein the inserting ground nail 18 is provided with two groups of hand wheels which respectively penetrate through two ends of the base 1 in a threaded rotation mode, the hand wheel 19 is arranged at the top end of the inserting ground nail 18, and after the positioning nail 16 is positioned, the hand wheels 19 at the two ends are rotated to drive the inserting ground nail 18 to be inserted into the ground for stable inserting and placing.

When the device is specifically used, after the device is pushed to a determined geographical position through the moving wheel 2, the electric push rod 15 is driven and started, the electric push rod 15 pushes the positioning nail 16, the positioning nail 16 is inserted into the ground for positioning, then the hand wheels 19 at two ends are rotated, the ground inserting nail 18 is driven to be inserted into the ground for stable ground inserting placement, the driving motor 11 is started, the driving motor 11 is rotated to drive the pull rope 13 on the winding roller 12 to wind or unwind, one side of the pull rope 13 is wound and the other side of the pull rope 13 is correspondingly unwound, the supporting plate 6 can rotate by taking the hinge joint of the supporting plate and the supporting column 5 as a rotation center, the wind direction sensing element 8 and the wind speed sensing element 9 on the supporting plate 6 are adjusted to be horizontal, and the wind speed and the wind direction are monitored by the wind direction sensing element 8 and the wind speed sensing element 9.

The utility model and its embodiments have been described above with no limitation, and the actual construction is not limited to the embodiments of the utility model as shown in the drawings. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the present utility model.

Claims (6)

1. Wind speed and direction indicator for bridge construction monitoring, comprising a base (1), and being characterized in that: the novel wind speed sensor comprises a base (1), wherein a movable wheel (2) is uniformly arranged below the base (1), a center positioning mechanism (3) and an auxiliary inserting and fixing assembly (4) are arranged on the base (1), a support column (5) is arranged at the center of the base (1), a support plate (6) is hinged to the top end of the support column (5), a support column (7) is arranged on the support plate (6), a wind direction sensing element (8) and a wind speed sensing element (9) are rotatably sleeved on the support column (7), the wind speed sensing element (9) is located above the wind direction sensing element (8), and a levelness adjusting mechanism (10) is arranged at the joint of the support plate (6) and the support column (5).

2. An anemometer for bridge construction monitoring as recited in claim 1, wherein: levelness adjustment mechanism (10) are including driving motor (11), take-up roller (12) and stay cord (13), all be provided with go-between (14) under the diapire both ends of backup pad (6), driving motor (11) set up two sets of and locate the both sides of support column (5), take-up roller (12) set up two sets of and are connected in the output of driving motor (11) respectively, the one end of stay cord (13) is connected in go-between (14), the other end winding of stay cord (13) is on take-up roller (12).

3. An anemometer for bridge construction monitoring as recited in claim 2, wherein: the center positioning mechanism (3) comprises an electric push rod (15) and a positioning nail (16), wherein the bottoms of the base (1) and the supporting columns (5) are respectively provided with a cavity (17) and are mutually communicated, the electric push rod (15) is installed in the cavities (17), the positioning nail (16) is arranged in the cavities (17) and is connected to the bottom of the electric push rod (15), and the bottom of the positioning nail (16) is moved to penetrate through the bottom wall of the cavities (17) and the bottom wall of the base (1).

4. An anemometer for bridge construction monitoring according to claim 3, wherein: the auxiliary inserting and fixing assembly (4) comprises inserting ground nails (18) and a hand wheel (19), wherein the inserting ground nails (18) are arranged in two groups and penetrate through two ends of the base (1) in a threaded rotation mode respectively, and the hand wheel (19) is arranged at the top end of the inserting ground nails (18).

5. An anemometer for bridge construction monitoring as recited in claim 4 wherein: the moving wheels (2) are provided with four groups.

6. An anemometer for bridge construction monitoring as recited in claim 5 wherein: the driving motor (11) is a servo motor.