CN221323836U - Non-contact hydrologic monitoring device installing support - Google Patents

Abstract

The utility model discloses a non-contact type hydrologic monitoring device mounting bracket in the technical field of hydrologic monitoring, which comprises a cross rod for mounting a monitoring device and a mounting table for mounting the cross rod, wherein the mounting table is fixedly connected with a mounting carrier through a side wall, the cross rod is in rotating fit with the mounting table to adjust the state of the cross rod, the cross rod comprises a transverse working state and an upturned maintenance state, a locking rod for locking the cross rod in the transverse working state or the upturned maintenance state is arranged on the cross rod in a penetrating manner, the cross rod can rotate upwards to enable the monitoring device mounted on the cross rod to be close to the mounting carrier, and meanwhile, the height of the monitoring device mounted on the cross rod is raised, so that maintenance personnel standing on the mounting carrier can easily operate the monitoring device, and the later debugging and maintenance are simpler and more convenient.

Description

Non-contact hydrologic monitoring device installing support

Technical Field

The utility model relates to the technical field of hydrologic monitoring, in particular to a non-contact hydrologic monitoring device mounting bracket.

Background

The non-contact hydrologic monitoring device mainly comprises ultrasonic waves, a radar flowmeter or a water level gauge and the like, a common non-contact monitoring device mounting bracket is mostly a steel pipe for mounting the monitoring device, the steel pipe is fixed on a stand column, the stand column is fixed on a shore or a bridge, the length of the steel pipe is determined according to the effective height of a flowmeter and a water level gauge sensor from the water surface and the beam range of the sensor, and the instrument is fixedly mounted at the front end of the steel pipe.

When flowmeter, fluviograph are installed in lateral wall such as bridge side, bank side, and the installing support is because the support arm is fixed, and instrument roll angle is very inconvenient with the regulation of vertical angle, does not have suitable operation equipment can be with maintenance debugging personnel slope down or horizontal lateral shifting to monitoring devices's mounted position, must dismantle whole installing support from the installation carrier, and this kind of mounting means is that instrument angle installation or cable are connected out problem and is very inconvenient to equipment debugging and maintenance.

Based on the above, the utility model designs a non-contact hydrologic monitoring device mounting bracket to solve the above problems.

Disclosure of utility model

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a non-contact hydrologic monitoring device installing support, is including the horizontal pole that is used for installing monitoring devices and the mount table that is used for installing the horizontal pole, mount table passes through lateral wall and installation carrier fixed connection, horizontal pole and mount table normal running fit are in order to adjust the state of horizontal pole, the horizontal pole includes horizontal operating condition and upwarp maintenance state, wear to be equipped with on the horizontal pole and be used for locking the horizontal pole in horizontal operating condition or upwarp maintenance state's locking lever.

As a further scheme of the utility model, the mounting table is transversely extended with a supporting part for lifting the cross rod, the supporting part is provided with a U-shaped cavity which is matched with the cross rod in size and used for guaranteeing the stability of the cross rod in a transverse working state, and the opening of the cavity is upwards for the cross rod to enter or leave the cavity.

As a further scheme of the utility model, the surface of the cross rod and the mounting table are provided with the fixing holes for penetrating the locking rod, and when the cross rod is in a transverse working state, the axis of the fixing holes formed on the surface of the cross rod is completely coincident with the axis of the fixing holes formed on the mounting table.

As a further scheme of the utility model, the distance from the fixing hole formed in the cross rod to the rotation axis of the cross rod is equal to the distance from the top end surface of the mounting table to the rotation axis of the cross rod.

As a further scheme of the utility model, a plurality of fixing holes are formed in the cross rod along the axis direction, the locking rod is arranged in the fixing holes at different positions on the surface of the cross rod in a penetrating way, and the cross rod can hover at different angles through the contact of the locking rod and the top wall of the mounting table.

As a further scheme of the utility model, both ends of the locking rod are provided with anti-withdrawal pieces for preventing the locking rod from withdrawing from the fixing holes.

As a further scheme of the utility model, the anti-withdrawal part is a nut in threaded engagement with the locking rod, a bolt in inserted fit with the locking rod or a bolt head fixedly connected with the locking rod.

As a further scheme of the utility model, the surface of the cross rod is fixedly provided with a pull ring.

As a further scheme of the utility model, an inclined strut is fixedly arranged between the mounting table and the supporting part.

The utility model has the following beneficial effects:

According to the utility model, the cross rod is rotatably arranged at the upper end of the mounting table, the cross rod can be rotated upwards to be in an upturned maintenance state, in the subsequent debugging and maintenance processes, the horizontal distance between the end of the cross rod, on which the monitoring device is arranged, and the mounting carrier is reduced, and the mounting table is fixed at the side edge of the mounting carrier, so that the horizontal distance between the monitoring device and the mounting carrier is shortened, and the height of the monitoring device is increased, and the monitoring device can be finally positioned at a position which can debug and maintain the monitoring device in a standing state and is at a proper operation height.

In addition to the objects, features and advantages described above, the present utility model has other objects, features and advantages. The present utility model will be described in further detail with reference to the drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model. In the drawings:

Fig. 1 is a schematic diagram of the overall structure of the present utility model.

FIG. 2 is a diagram illustrating a debug status of the present utility model.

FIG. 3 is a schematic view of various embodiments of the locking lever and the anti-back-out member according to the present utility model.

Fig. 4 is a schematic view of the mounting structure of the present utility model.

FIG. 5 is a diagram illustrating another debug status according to the present utility model.

Legend description:

1. A cross bar; 2. a mounting table; 3. a support part; 4. a clamping part; 5. a locking lever; 6. a fixing hole; 7. an anti-withdrawal member; 8. a pull ring; 9. and (5) an inclined strut.

Detailed Description

Embodiments of the utility model are described in detail below with reference to the attached drawing figures, but the utility model can be practiced in a number of different ways, as defined and covered below.

Referring to fig. 1-5, the present utility model provides a technical solution: the utility model provides a non-contact hydrologic monitoring device installing support, is including the horizontal pole 1 that is used for installing monitoring devices and the mount table 2 that is used for installing horizontal pole 1, mount table 2 pass through lateral wall and installation carrier fixed connection, horizontal pole 1 and mount table 2 normal running fit are in order to adjust horizontal pole 1, and horizontal pole 1 includes horizontal operating condition and upwarp maintenance state, wears to be equipped with on the horizontal pole 1 and is used for locking horizontal pole 1 in horizontal operating condition or upwarp maintenance state's locking lever 5.

In this embodiment, through rotating the horizontal pole 1 and setting up on mount table 2, make the state of horizontal pole 11 can adjust, horizontal pole 1 has horizontal operating condition and upwarp maintenance state, can be direct with the hand or adopt the instrument to rotate horizontal pole 1 from horizontal operating condition upwards to upwarp maintenance state, because mount table 2 passes through the lateral wall and is connected with the installation carrier, then whole installing support just is in the side of installation carrier, for example the side of bridge or concrete lateral wall, and the operator stands on the top surface of installation carrier, when horizontal pole 1 upwards rotates to upwarp maintenance state from horizontal operating condition, not only horizontal distance can shorten between monitoring devices and the installation carrier of installation on horizontal pole 1, monitoring devices's height still can rise, monitor device on the horizontal pole 1 moves to a position that just can maintain it in a standing state, be in suitable operating height, be convenient for debug and maintain monitoring devices, wear to be equipped with on horizontal pole 1 and be used for locking horizontal pole 1 in horizontal operating condition and upwarp maintenance state's locking lever 5, guarantee the stability when horizontal pole 1 is in horizontal operating condition, simultaneously when horizontal pole 1 is in upwarp maintenance state and maintenance device is not needed to monitor device on horizontal pole 1, it is more convenient to carry out both monitor device and maintenance device on horizontal pole 1.

As shown in fig. 1-5, a supporting part 3 for lifting the cross rod 1 transversely extends from the mounting table 2, a cavity matched with the cross rod 1 in size and used for guaranteeing the stability of the cross rod 1 in a transverse working state is formed in the supporting part 3, and the opening of the cavity faces upwards for the cross rod 1 to enter or leave the cavity.

In the embodiment, the supporting part 3 horizontally extends out of the mounting table 2, a cavity matched with the cross rod 1 in size is formed in the supporting part 3, the cavity can be U-shaped or V-shaped, the cross rod 1 can be just clamped into the cavity when in a transverse working state, the cross rod 1 is limited and supported by the contact of the side wall and the bottom wall of the cavity with the cross rod 1, wind vibration of the cross rod 1 in the transverse working state is reduced, a monitoring device mounted on the cross rod 1 is guaranteed to have a good working state, and accuracy of a final monitoring result is guaranteed; the cavity can be formed by forming through grooves on the surface of the supporting part 3, and the two clamping parts 4 can be arranged on the surface of the supporting part 3 at intervals according to the diameter of the cross rod 1, and the space between the clamping parts 4 and the supporting part 3 is the cavity.

As shown in fig. 1-5, the surface of the cross bar 1 and the mounting table 2 are provided with fixing holes 6 for penetrating the locking bar 5, and when the cross bar 1 is in a transverse working state, the axis of the fixing holes 6 formed on the surface of the cross bar 1 is completely overlapped with the axis of the fixing holes 6 formed on the mounting table 2.

In this embodiment, when the axis of the fixing hole 6 formed in the cross bar 1 and the mounting table 2 completely coincide, the locking rod 5 passes through the fixing hole 6 formed in the cross bar 1 and the mounting table 2 at the same time, and the cross bar 1 is locked in a transverse working state by restricting the rotation of the cross bar 1 by the locking rod 5.

As shown in fig. 2, the distance from the fixing hole 6 formed on the cross bar 1 to the rotation axis of the cross bar 1 is equal to the distance from the top end surface of the mounting table 2 to the rotation axis of the cross bar 1.

In this embodiment, the distance from the fixing hole 6 formed on the cross bar 1 to the rotation axis of the cross bar 1 is equal to the distance from the top end surface of the mounting table 2 to the rotation axis of the cross bar 1, the locking bar 5 is firstly pulled away from the fixing hole 6, then the cross bar 1 is rotated upwards to a vertical state, at this time, the locking bar 5 is inserted into the fixing hole 6 formed on the cross bar 1, the locking bar 5 just contacts with the top surface of the mounting table 2, the cross bar 1 keeps a tilted maintenance state by the contact between the locking bar 5 and the top surface of the mounting table 2, the subsequent maintenance and debugging of the monitoring device are more convenient, the distance from the fixing hole 6 on the supporting part 3 to the mounting carrier is not too long, and the locking bar 5 is conveniently inserted into the fixing hole 6 and separated from the fixing hole 6 manually on the mounting carrier.

As shown in fig. 4-5, a plurality of fixing holes 6 are formed in the cross bar 1 along the axial direction, the locking bar 5 is arranged in the fixing holes 6 at different positions on the surface of the cross bar 1 in a penetrating manner, and the cross bar 1 can hover at different angles by contacting the locking bar 5 with the top wall of the mounting table 2.

In this embodiment, the cross bar 1 is first rotated upwards to leave the cavity, at this time, the locking bar 5 is separately inserted into the fixing hole 6 formed on the surface of the cross bar 1, and by inserting the locking bar 5 into the fixing hole 6 at a different position on the surface of the cross bar 1, the cross bar 1 can be suspended at different inclined angles by contacting the locking bar 5 with the top wall of the mounting table 2, under different angles of the cross bar 1, the height of the monitoring device on the cross bar 1 will be different, when the length of the cross bar 1 is longer, the cross bar 1 can be kept in an inclined state, so that the height of the monitoring device on the cross bar 1 will be more convenient for maintenance and debugging, and it should be noted that if the cross bar 1 needs to be rotated to an inclined state, the mounting table 2 needs to ensure that the rotation axis of the cross bar 1 is higher than the top wall of the mounting carrier or has a certain horizontal distance from the top wall of the mounting carrier during installation, so that the cross bar 1 has a space for rotating to an inclined maintenance state, and likewise, the cross bar 1 can be directly rotated 180 ° to be placed on the top wall of the mounting carrier, so that the cross bar 1 can be selected according to actual conditions, and so that in most cases, the cross bar 1 can be kept at a proper angle.

As shown in fig. 1 to 3, both ends of the locking lever 5 are provided with a withdrawal preventing member 7 for preventing the locking lever 5 from withdrawing from the fixing hole 6.

In this embodiment, the two ends of the locking rod 5 are both provided with the anti-withdrawal pieces 7, so as to prevent the locking rod 5 from being separated from the fixing hole 6, and when the locking rod 5 needs to be withdrawn from the fixing hole 6 formed in the cross rod 1 or the mounting table 2, only one of the anti-withdrawal pieces 7 needs to be disassembled, so that the locking rod 5 can be withdrawn from the fixing hole 6 from the other end.

As shown in fig. 3, the anti-back-out member 7 is a nut in threaded engagement with the locking bar 5, or is a bolt in plug-in engagement with the locking bar 5, or is a bolt head fixedly connected with the locking bar 5.

In this embodiment, the anti-loosening member 7 is a nut or a bolt head, at most only one of the anti-loosening members 7 at two ends of the locking rod 5 can be a non-detachable bolt head, when the cross section of the locking rod 5 is circular, the anti-loosening member 7 can be a nut or a bolt, and when the cross section of the locking rod 5 is elliptical, regular polygon or irregular, the anti-loosening member 7 can be a bolt.

As shown in fig. 1-5, a pull ring 8 is fixedly arranged on the surface of the cross rod 1.

In this embodiment, the pull ring 8 is fixedly installed on the surface of the cross rod 1, and the pull ring 8 can be hooked by a tool with a hook in the subsequent use process, so that the force is conveniently applied to the cross rod 1 to rotate.

As shown in fig. 1 to 5, an inclined strut 9 is fixedly installed between the mounting table 2 and the supporting portion 3 at the top of the mounting table 2.

In this embodiment, the supporting portion 3 not only needs to limit the vibration of the cross bar 1, but also needs to bear the weight of the cross bar 1, and the supporting capability of the supporting portion 3 is increased by the diagonal brace 9, so as to prevent the supporting portion 3 from being deformed by the pressure of the cross bar 1.

The above is only a preferred embodiment of the present utility model, and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (9)

1. The utility model provides a non-contact hydrologic monitoring device installing support, is including horizontal pole (1) that are used for installing monitoring devices and mount table (2) that are used for installing horizontal pole (1), mount table (2) are through lateral wall and installation carrier fixed connection, horizontal pole (1) and mount table (2) normal running fit are in order to adjust the state of horizontal pole (1), its characterized in that:

The transverse rod (1) comprises a transverse working state and an upturned maintenance state, and a locking rod (5) for locking the transverse rod (1) in the transverse working state or the upturned maintenance state is arranged on the transverse rod (1) in a penetrating mode.

2. The non-contact hydrographic monitoring device mounting bracket of claim 1, wherein: the mounting table (2) is transversely extended with a supporting part (3) for lifting the cross rod (1), a cavity matched with the cross rod (1) in size and used for clamping the cross rod to ensure the stability of the cross rod (1) in a transverse working state is formed in the supporting part (3), and the cross rod (1) is upwards supplied to enter or leave the cavity through an opening of the cavity.

3. The non-contact hydrographic monitoring device mounting bracket of claim 1, wherein: the fixing holes (6) used for penetrating the locking rods (5) are formed in the surface of the cross rod (1) and the mounting table (2), and when the cross rod (1) is in a transverse working state, the axes of the fixing holes (6) formed in the surface of the cross rod (1) are completely coincident with the axes of the fixing holes (6) formed in the mounting table (2).

4. A non-contact hydrographic monitoring device mounting bracket as defined in claim 3, wherein: the distance from the fixing hole (6) formed in the cross rod (1) to the rotation axis of the cross rod (1) is equal to the distance from the top end surface of the mounting table (2) to the rotation axis of the cross rod (1).

5. A non-contact hydrographic monitoring device mounting bracket as defined in claim 3, wherein: a plurality of fixing holes (6) are formed in the cross rod (1) along the axis direction, the locking rod (5) is arranged in the fixing holes (6) in different positions on the surface of the cross rod (1) in a penetrating mode, and the cross rod (1) is suspended at different angles through contact between the locking rod (5) and the top wall of the mounting table (2).

6. A non-contact hydrographic monitoring device mounting bracket as defined in claim 3, wherein: both ends of the locking rod (5) are provided with anti-withdrawal pieces (7) for preventing the locking rod (5) from withdrawing from the fixing holes (6).

7. The non-contact hydrographic monitoring device mounting bracket of claim 6, wherein: the anti-withdrawal part (7) is a screw cap which is in threaded engagement with the locking rod (5), or is a bolt which is in plug-in fit with the locking rod (5), or is a bolt head which is fixedly connected with the locking rod (5).

8. The non-contact hydrographic monitoring device mounting bracket of claim 1, wherein: the surface of the cross rod (1) is fixedly provided with a pull ring (8).

9. The non-contact hydrographic monitoring device mounting bracket of claim 1, wherein: an inclined strut (9) is fixedly arranged between the mounting table (2) and the supporting part (3).