CN210827368U - Ultrasonic double-protective wing measurement and control gate - Google Patents

Abstract

The utility model provides an ultrasonic double-wing measurement and control gate, which comprises a double-wing gate, a sill, a guard plate, a stand column, a work box and a solar system; the number of the stand columns is 2, a guard plate is arranged on the outer side of each stand column, a working box is arranged at the top end of each stand column, a bottom sill is arranged at the bottom end of each stand column, and a plurality of ultrasonic probes are arranged in grooves of the stand columns; the double-protective wing gate comprises a gate plate and a wing plate, the gate plate is buckled between the chutes of the two upright posts, a gate position sensor is arranged on the gate plate, a flow stabilizing plate is arranged at the bottom end of the gate plate, and the wing plate covers the opening end of the groove; the solar energy gate protection device is characterized in that the working box is fixedly connected with a solar energy system, a rack type hoist and a control system are arranged in the working box, the rack type hoist is connected with a double-wing gate, and the control system is linearly connected with the ultrasonic probe and the gate position sensor. The utility model discloses it is simple convenient to survey the flow, requires lowly to the attitude, can accurately survey the floodgate flow, has realized the purpose through adjusting floodgate position control floodgate flow size.

Description

Ultrasonic double-protective wing measurement and control gate

Technical Field

The utility model relates to a observe and control the gate field, specifically, relate to an ultrasonic wave double wing observes and controls gate.

Background

The traditional definite flow measurement mode has the problems of fuzzy water quantity measurement, high requirement on flow state, difficult flow measurement and the like; and the channel generally adopts a split type measuring mode of front measurement, rear control, front measurement and the like. The defects are puzzled to industrial personnel for a long time, but no better solution exists for many years, so that the application of gate water measurement is limited to a certain extent, the purpose of controlling the magnitude of the gate flow by adjusting the gate position is not realized, and an integrated measurement and control device capable of solving the problems is urgently needed.

SUMMERY OF THE UTILITY MODEL

The defect to among the prior art, the utility model aims at providing an ultrasonic wave double wing observes and controls gate, the utility model discloses a gather floodgate position and velocity of flow synthetic flow, it is simple convenient to flow measurement, and is low to the attitude requirement, can accurately survey the cross brake flow, has realized through the purpose of adjusting floodgate position control cross brake flow size.

According to one aspect of the utility model, an ultrasonic double-wing measurement and control gate is provided, which comprises a double-wing gate 1, a sill 2, a guard plate 3, a stand column 4, a work box 5 and a solar system 6;

the number of the upright columns 4 is 2, grooves 41 and sliding grooves 42 are formed in the inner sides of the upright columns 4, the outer sides of the upright columns are provided with guard plates 3, the top ends of the upright columns are provided with working boxes 5, the bottom ends of the upright columns are provided with bottom sills 2, a plurality of ultrasonic probes 7 are arranged in the grooves 41 from top to bottom, the ultrasonic probes 7 are arranged in the grooves 41 from dense to sparse, and channels are divided into monitoring areas with different multilayer layer heights from the channel bottom to the gate top;

the double-wing gate 1 comprises a gate plate 11 and wing plates 12, wherein the gate plate 11 is slidably mounted between the chutes 42 of the two upright posts 4, a gate position sensor is arranged on the gate plate 11, a stable flow plate 8 in a stable flow state is arranged at the bottom end of the gate plate 11, and the wing plates 12 cover the opening end of the groove 41;

the solar energy gate is characterized in that the working box 5 is fixedly connected with the solar energy system 6, a rack type hoist and a control system are arranged in the working box 5, the rack type hoist is connected with the double-wing gate 1, and the control system is linearly connected with the ultrasonic probe 7 and the gate position sensor.

Preferably, each of the pillars 4 is provided with 2 grooves 41, and the grooves 41 are symmetrically arranged on two sides of the sliding groove 42.

Preferably, 8 ultrasonic probes 7 are arranged in each groove 41.

Preferably, the ultrasonic probe 7 divides the channel from the bottom of the channel to the top of the gate into 8 monitoring areas, and 4 ultrasonic probes 7 are arranged in each monitoring area.

Preferably, the ultrasonic probe 7 is disposed obliquely in the recess 41, and the two ultrasonic probes 7 on the oblique diagonal line in the monitoring area are disposed opposite to each other.

Preferably, the bottom end of the sliding groove 42 abuts against the sill 2, the top end of the sliding groove abuts against the work box 5, the length of the groove 41 is smaller than that of the sliding groove 42, and the groove 41 is arranged at the lower part of the upright post 4.

Preferably, the double-wing gate 1 is opened and closed in various manners, and the double-wing gate 1 is opened and closed by driving of a rack, a screw or a steel wire rope.

Preferably, the solar energy system 6 comprises a solar panel, a solar rod and a storage battery, wherein the lower end of the solar rod penetrates through the working box 5 and is arranged on the outer side of the upright post 4.

Preferably, when the double-wing gate is closed, the wing plate 12 covers the opening end of the groove 41 to protect the ultrasonic probe 7.

Preferably, the double-wing gate 1, the sill 2 and the pillar 4 are all cast from aluminum alloy.

The sill is arranged at the bottom of the double-protective wing gate and plays a role of restricting the section when measuring the flow velocity; the guard plate is arranged on the outer side of the upright post to protect the electricity in the upright post; the upright post is used as a supporting mechanism of the wing door; one wing plate is arranged in the upstream direction and the downstream direction of the gate and serves as a protection mechanism of the ultrasonic probe; the solar energy system provides a necessary power source for the rack hoist. The rack type hoist controls the opening or closing of the flashboard on the gate, the ultrasonic probe measures the flow velocity of passing the gate, and the gate position sensor measures the lifting height of the flashboard.

The working principle is as follows: sill, stand and flashboard surround into a standard section, the multilayer probe of setting falls into a plurality of regions with the channel from the canal bottom to the floodgate top, and monitoring area is by bottom to top, arrange from close to sparse, all there is a set of 4 ultrasonic probe in every region, control system is through installing the ultrasonic probe on the stand, measure the lockage velocity of flow with the ultrasonic wave time difference method, calculate the lockage flow with the velocity of flow and force the section, be B when the flashboard width, the floodgate position sensor measures the flashboard and rises to the height and be H, when ultrasonic probe measured the lockage velocity of flow and is V, then can calculate lockage flow Q ═ VHB.

Compared with the prior art, the utility model discloses following beneficial effect has:

(1) the utility model relates to an ultrasonic wave double-protection wing measurement and control gate, through gathering the floodgate position and velocity of flow and synthesizing into flow, the current surveying is simple and convenient, and is low to the attitude requirement, can accurately survey the brake flow, has realized the purpose of controlling the size of brake flow through adjusting the floodgate position;

(2) the utility model relates to an ultrasonic wave double-wing measurement and control gate is provided with a plurality of layers of probes, channels are divided into a plurality of areas from the bottom of a canal to the top of the gate, and a group of 4 ultrasonic probes are arranged in each area from top to bottom from dense to sparse, thereby reducing the influence of the flow state in the channels on the measurement precision and increasing the accuracy;

(3) the utility model relates to an ultrasonic wave double wing observes and controls gate has solved the tradition and has made clear and definite the flow measurement fuzzy the water yield and measure, to the attitude requirement height, the difficult scheduling problem of flow measurement.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic structural perspective view of the ultrasonic double-flap measurement and control gate of the present invention;

FIG. 2 is a schematic view of the structure of the ultrasonic dual-flap measurement and control gate of the present invention;

FIG. 3 is a schematic left view of the structure of the ultrasonic double-flap measurement and control gate of the present invention;

fig. 4 is a schematic view of the ultrasonic probe of the present invention installed in a pillar;

fig. 5 is a schematic view of the installation of the ultrasonic probe of the present invention;

in fig. 1: the device comprises a double-wing gate 1, a sill 2, a guard plate 3, a stand column 4, a work box 5, a solar system 6, an ultrasonic probe 7, a flow stabilizing plate 8, a gate plate 11, a wing plate 12, a groove 41 and a sliding groove 42.

Detailed Description

The present invention will be described in detail with reference to the following embodiments. The following examples will assist those skilled in the art in further understanding the present invention, but are not intended to limit the invention in any way. It should be noted that various changes and modifications can be made by one skilled in the art without departing from the spirit of the invention. These all belong to the protection scope of the present invention.

Examples

The present embodiment provides an ultrasonic dual-flap measurement and control gate, the structure of which is shown in fig. 1-5: the device comprises a double-wing gate 1, a sill 2, a guard plate 3, a stand column 4, a working box 5 and a solar system 6;

the number of the upright columns 4 is 2, grooves 41 and sliding grooves 42 are formed in the inner sides of the upright columns 4, the outer sides of the upright columns are provided with guard plates 3, the top ends of the upright columns are provided with working boxes 5, the bottom ends of the upright columns are provided with bottom sills 2, a plurality of ultrasonic probes 7 are arranged in the grooves 41 from top to bottom, the ultrasonic probes 7 are arranged in the grooves 41 from dense to sparse, and channels are divided into monitoring areas with different multilayer layer heights from the channel bottom to the gate top;

the double-wing gate 1 comprises a gate plate 11 and wing plates 12, wherein the gate plate 11 is buckled between the chutes 42 of the two upright posts 4, a gate position sensor is arranged on the gate plate 11, a stable flow plate 8 in a stable flow state is arranged at the bottom end of the gate plate 11, and the wing plates 12 cover the opening end of the groove 41;

the solar energy gate is characterized in that the working box 5 is fixedly connected with the solar energy system 6, a rack type hoist and a control system are arranged in the working box 5, the rack type hoist is connected with the double-wing gate 1, and the control system is linearly connected with the ultrasonic probe 7 and the gate position sensor.

Further, all be equipped with 2 recesses 41 on the stand 4, just recess 41 symmetry sets up the both sides at spout 42.

Further, 8 ultrasonic probes 7 are arranged in each groove 41.

Furthermore, the ultrasonic probe 7 divides the channel from the bottom of the channel to the top of the gate into 8 monitoring areas, and 4 ultrasonic probes 7 are arranged in each monitoring area.

Further, the ultrasonic probes 7 are arranged obliquely in the groove 41, and the two ultrasonic probes 7 on the oblique diagonal line in the monitoring area are arranged oppositely.

Further, the bottom end of the sliding groove 42 abuts against the sill 2, the top end of the sliding groove abuts against the work box 5, the length of the groove 41 is smaller than that of the sliding groove 42, and the groove 41 is arranged at the lower part of the upright post 4.

Furthermore, the double-protection-wing gate 1 is opened and closed in various manners, and the double-protection-wing gate 1 is driven to be opened and closed through a rack, a screw or a steel wire rope.

Further, solar energy system 6 includes solar panel, solar pole and battery, the lower extreme of solar pole runs through work box 5 and sets up in the outside of stand 4.

Further, when the double-wing gate is closed, the wing plate 12 covers the opening end of the groove 41 to protect the ultrasonic probe 7.

Further, the double-wing gate 1, the sill 2 and the upright post 4 are all cast from aluminum alloy.

The sill is arranged at the bottom of the double-protective wing gate and plays a role of restricting the section when measuring the flow velocity; the guard plate is arranged on the outer side of the upright post to protect the electricity in the upright post; the upright post is used as a supporting mechanism of the wing door; one wing plate is arranged in the upstream direction and the downstream direction of the gate and serves as a protection mechanism of the ultrasonic probe; the solar energy system provides a necessary power source for the rack hoist. The rack type hoist controls the opening or closing of the flashboard on the gate, the ultrasonic probe measures the flow velocity of passing the gate, and the gate position sensor measures the lifting height of the flashboard.

The working principle is as follows: sill, stand and flashboard surround into a standard section, the multilayer probe of setting falls into a plurality of regions with the channel from the canal bottom to the floodgate top, and monitoring area is by bottom to top, arrange from close to sparse, all there is a set of 4 ultrasonic probe in every region, control system is through installing the ultrasonic probe on the stand, measure the lockage velocity of flow with the ultrasonic wave time difference method, calculate the lockage flow with the velocity of flow and force the section, be B when the flashboard width, the floodgate position sensor measures the flashboard and rises to the height and be H, when ultrasonic probe measured the lockage velocity of flow and is V, then can calculate lockage flow Q ═ VHB.

The embodiment has the following beneficial effects:

(1) the flow is simulated by collecting the gate position and the flow velocity, the flow measurement is simple and convenient, the requirement on the flow state is low, the flow of the passing gate can be accurately measured, and the purpose of controlling the flow of the passing gate by adjusting the gate position is realized;

(2) the channel is divided into a plurality of areas from the bottom of the channel to the top of the gate by the aid of the multi-layer probes, the monitoring areas are arranged from top to bottom and from dense to sparse, and each area is provided with a group of 4 ultrasonic probes, so that the influence of flow state in the channel on measurement precision is reduced, and accuracy is improved;

(3) the problems of fuzzy measurement of water quantity, high requirement on flow state, difficult flow measurement and the like of the traditional definite flow measurement are solved.

The foregoing description of the specific embodiments of the invention has been presented. It is to be understood that the present invention is not limited to the specific embodiments described above, and that various changes and modifications may be made by those skilled in the art within the scope of the appended claims without departing from the spirit of the invention.

Claims (10)

1. An ultrasonic double-wing measurement and control gate is characterized by comprising a double-wing gate (1), a sill (2), a guard plate (3), a stand column (4), a working box (5) and a solar system (6);

the number of the upright columns (4) is 2, grooves (41) and sliding grooves (42) are formed in the inner sides of the upright columns (4), a protective plate (3) is arranged on the outer side of each upright column, a working box (5) is arranged at the top end of each upright column, a sill (2) is arranged at the bottom end of each upright column, a plurality of ultrasonic probes (7) are arranged in each groove (41), the ultrasonic probes (7) are arranged in the grooves (41) from top to bottom from dense to sparse, and channels are divided into monitoring areas with different multilayer layer heights from the bottoms of the channels to the tops of the gates;

the double-wing gate (1) comprises a gate plate (11) and wing plates (12), wherein the gate plate (11) is slidably mounted between chutes (42) of two upright posts (4), a gate position sensor is arranged on the gate plate (11), a stable flow plate (8) is arranged at the bottom end of the gate plate (11), and the wing plates (12) are covered at the opening ends of the grooves (41);

the solar energy gate is characterized in that the working box (5) is fixedly connected with the solar energy system (6), a rack type hoist and a control system are arranged in the working box (5), the rack type hoist is connected with the double-wing gate (1), and the control system is linearly connected with the ultrasonic probe (7) and the gate position sensor.

2. The ultrasonic double-wing measurement and control gate according to claim 1, wherein 2 grooves (41) are formed in each of the pillars (4), and the grooves (41) are symmetrically formed on two sides of the sliding groove (42).

3. The ultrasonic double-wing measurement and control gate according to claim 2, wherein 8 ultrasonic probes (7) are arranged in each groove (41).

4. The ultrasonic double-wing measurement and control gate according to claim 3, wherein the ultrasonic probes (7) divide the channel from the bottom of the channel to the top of the gate into 8 monitoring areas, and 4 ultrasonic probes (7) are arranged in each monitoring area.

5. The ultrasonic double-wing measurement and control gate according to claim 4, characterized in that the ultrasonic probes (7) are arranged obliquely in the groove (41), and the two ultrasonic probes (7) on the oblique diagonal in the monitoring area are arranged oppositely.

6. The ultrasonic measurement and control gate with double wings as claimed in claim 1, wherein the bottom end of the sliding groove (42) abuts against the sill (2), the top end of the sliding groove abuts against the work box (5), the length of the groove (41) is smaller than that of the sliding groove (42), and the groove (41) is arranged at the lower part of the upright post (4).

7. The ultrasonic double-wing measurement and control gate according to claim 1, wherein the double-wing gate (1) is opened and closed in multiple ways, and the double-wing gate (1) is opened and closed by a rack, a screw or a steel wire rope.

8. The ultrasonic measurement and control gate with double wings as claimed in claim 1, wherein the solar system (6) comprises a solar panel, a solar pole and a storage battery, and the lower end of the solar pole is arranged outside the upright post (4) through the working box (5).

9. The ultrasonic double-wing measurement and control gate according to claim 8, wherein when the double-wing gate is closed, the wing plate (12) covers the opening end of the groove (41) to protect the ultrasonic probe (7).

10. The ultrasonic double-wing measurement and control gate according to claim 1, wherein the double-wing gate (1), the sill (2) and the pillar (4) are all cast from aluminum alloy.

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