CN214200048U - Wireless intelligent ice detection sensing device - Google Patents

Abstract

The utility model discloses a wireless intelligence surveys ice sensing device, including removing frame, probe rod and tooth piece, the upper surface that removes the frame is provided with servo controller and radio signal transmitter respectively, and removes the upper surface mounting of frame and have elevator motor, elevator motor's upper end is connected with the lifter, and the surface of lifter is connected with the lifter plate, the upper surface mounting of lifter plate has rotating electrical machines, the one end of lifter plate is stretched into the pole and runs through, and stretches into the upper surface connection of pole and have the kelly to the kelly with stretch into and be connected with spacing spring between the pole, the internal fixed surface who stretches into the pole has the tooth piece. This wireless intelligence surveys ice sensing device is provided with the gauge rod, stretches into through the gauge rod and surveys under water, then carries out wireless transmission through the wireless signal transmitter and transmits the thickness of ice surface and temperature under water to researcher's computer in, realizes long-range wireless intelligent monitoring's purpose.

Description

Wireless intelligent ice detection sensing device

Technical Field

The utility model relates to an ice surface measures technical field, specifically is a wireless intelligence surveys ice sensing device.

Background

In the lower region of temperature, the ice surface of some lakes is often frozen, and the meteorological office needs to collect data through the measurement to ice surface thickness to compare with the data of the past year, thereby monitor the change of environment, but current survey ice device has some problems in the in-service use process:

firstly, the existing ice measuring device usually measures the thickness of the ice surface on the ice surface in a wired transmission mode, and the monitoring mode is very unsafe because workers are required to be on the spot and the ice surface is unstable;

secondly, when the temperature of the existing ice measuring device is too low, the sensor positioned below the ice surface may lose the measuring function due to the too low temperature, and the stable operation of the ice measuring device cannot be ensured by completely depending on the measuring mode of the sensor.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a wireless intelligence surveys ice sensing device to solve the problem that the monitoring mode that above-mentioned background art provided is not good and the sensor can't the stable monitoring because of the low temperature.

In order to achieve the above object, the utility model provides a following technical scheme: a wireless intelligent ice measuring sensing device comprises a moving frame, a detection rod and a tooth block, wherein the upper surface of the moving frame is respectively provided with a servo controller and a wireless signal transmitter, the upper surface of the moving frame is provided with a lifting motor, the upper end of the lifting motor is connected with the lifting rod, the outer surface of the lifting rod is connected with a lifting plate, the upper surface of the lifting plate is provided with a rotating motor, the lower end of the rotating motor is connected with a driving gear, one end of the lifting plate is penetrated by an extending rod, the upper surface of the extending rod is connected with a clamping rod, a limiting spring is connected between the clamping rod and the extending rod, the extending rod is internally connected with a sliding rod, the outer surface of the sliding rod is connected with a displacement gear, one end of the displacement gear penetrates through the outer surface of the sliding rod, one end of the displacement gear, which is positioned inside the sliding rod, is connected with a transmission gear, and the outer surface of the transmission gear is connected with the detection rod, and a tooth block is fixed on the inner surface of the extending rod.

Preferably, the lifting rod is in threaded connection with the lifting plate, and the lifting plate and the moving frame form a sliding structure.

Preferably, the driving gear is connected with the extending rod in a meshed mode, and the driving gear and the lifting plate form a rotating structure.

Preferably, the clamping rod and the extending rod form a sliding structure, and the clamping rod and the extending rod form an elastic structure through a limiting spring.

Preferably, the slide bar and the clamping bar form a clamping structure, the slide bar and the displacement gear form a rotating structure, and the displacement gear is in meshed connection with the transmission gear.

Preferably, the tooth blocks are distributed on the inner surface of the extending rod at equal intervals, and the extending rod is in meshed connection with the displacement gear through the tooth blocks.

Compared with the prior art, the beneficial effects of the utility model are that: this wireless intelligence surveys ice sensing device:

1. the device is provided with a detection rod, the detection rod extends into the water for detection, and then a wireless signal transmitter is used for wireless transmission to transmit the thickness of the ice surface and the temperature under the water to a computer of a researcher, so that the aim of remote wireless intelligent monitoring is fulfilled;

2. the rotary motor is arranged, and the detection rod is driven to rotate by the rotary motor, so that the detection rod can measure the thickness of the ice surface in a mode of directly contacting the ice surface when the sensor fails, and the condition that the monitoring device fails due to the failure of the temperature sensor is effectively prevented;

3. be provided with and stretch into the pole, stretch into the pole and pass through the pick block and make the probe rod can overturn at the in-process of lapse, drive the pivoted through the driving gear simultaneously and stretch into the pole for the ice surface around the probe rod can not freeze and lead to the probe rod to be frozen under water and can't continue to monitor the ice surface.

Drawings

FIG. 1 is a schematic overall front sectional view of the present invention;

FIG. 2 is a schematic view of the front cross-sectional structure of the transmission gear and the detecting rod of the present invention;

FIG. 3 is a schematic view of the overall sectional view of the present invention;

fig. 4 is the schematic view of the sectional side view structure of the lifter and the lifter plate of the present invention.

In the figure: 1. a movable frame; 2. a servo controller; 3. a wireless signal transmitter; 4. a lifting motor; 5. a lifting rod; 6. a lifting plate; 7. a rotating electric machine; 8. a driving gear; 9. extending into the rod; 10. a clamping rod; 11. a limiting spring; 12. a slide bar; 13. a displacement gear; 14. a transmission gear; 15. a probe rod; 16. a tooth block.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a wireless intelligent ice measuring sensing device comprises a moving frame 1, a servo controller 2, a wireless signal emitter 3, a lifting motor 4, a lifting rod 5, a lifting plate 6, a rotating motor 7, a driving gear 8, an extending rod 9, a clamping rod 10, a limiting spring 11, a sliding rod 12, a displacement gear 13, a transmission gear 14, a detection rod 15 and a tooth block 16, wherein the servo controller 2 and the wireless signal emitter 3 are respectively arranged on the upper surface of the moving frame 1, the lifting motor 4 is arranged on the upper surface of the moving frame 1, the lifting rod 5 is connected to the upper end of the lifting motor 4, the lifting plate 6 is connected to the outer surface of the lifting rod 5, the rotating motor 7 is arranged on the upper surface of the lifting plate 6, the driving gear 8 is connected to the lower end of the rotating motor 7, one end of the lifting plate 6 is penetrated by the extending rod 9, the clamping rod 10 is connected to the upper surface of the extending rod 9, and the limiting spring 11 is connected between the clamping rod 10 and the extending rod 9, the inside of stretching into pole 9 is connected with slide bar 12, and the surface of slide bar 12 is connected with displacement gear 13 to the surface of slide bar 12 is run through to the one end of displacement gear 13, and the one end that displacement gear 13 is located slide bar 12 inside is connected with drive gear 14, and the surface of drive gear 14 is connected with detection pole 15, and the internal surface that stretches into pole 9 is fixed with cogged block 16, and the surface of detection pole 15 is provided with temperature-sensing ware, range finding inductor and pressure sensor respectively.

The lifting rod 5 is in threaded connection with the lifting plate 6, the lifting plate 6 and the moving frame 1 form a sliding structure, and the lifting rod 5 rotates and drives the lifting plate 6 to slide above the moving frame 1 through threaded connection with the lifting plate 6.

The driving gear 8 is connected with the stretching rod 9 in a meshed mode, the driving gear 8 and the lifting plate 6 form a rotating structure, the driving gear 8 is driven by the rotating motor 7 to rotate, and the stretching rod 9 is driven to rotate through connection with the stretching rod 9 in a meshed mode.

The clamping rod 10 and the extending rod 9 form a sliding structure, the clamping rod 10 and the extending rod 9 form an elastic structure through a limiting spring 11, the clamping rod 10 slides and stretches the limiting spring 11, and the clamping rod 10 is enabled to be separated from the clamping with the sliding rod 12.

The slide rod 12 and the clamping rod 10 form a clamping structure, the slide rod 12 and the displacement gear 13 form a rotating structure, the displacement gear 13 is meshed with the transmission gear 14, the slide rod 12 slides downwards and drives the displacement gear 13 to slide downwards, and the displacement gear 13 rotates through meshing with the gear block 16 and drives the transmission gear 14 to rotate.

The tooth blocks 16 are distributed on the inner surface of the extending rod 9 at equal intervals, the extending rod 9 is in meshed connection with the displacement gear 13 through the tooth blocks 16, and the tooth blocks 16 drive the displacement gear 13 to rotate through meshing with the displacement gear 13 in the process that the displacement gear 13 slides downwards along with the sliding rod 12.

The working principle is as follows: when the wireless intelligent ice measuring sensing device is used, firstly, as shown in fig. 1-4, the moving frame 1 is pushed to the ice surface to be measured, then a hole with a diameter slightly larger than that of the extending rod 9 is drilled on the ice surface through a drilling device, then the extending rod 9 penetrates through the outer surface of the lifting plate 6 and is inserted into the ice hole until the lower surface of the upper end extension part of the extending rod 9 is attached to the upper surface of the driving gear 8, at the moment, the driving gear 8 is slightly rotated, so that the driving gear 8 can be meshed with the extending rod 9, therefore, the extending rod 9 slides downwards under the action of gravity and is meshed with the driving gear 8, then the sliding rod 12 is inserted into the extending rod 9, the sliding rod 12 drives the displacement gear 13 to synchronously slide downwards in the downward sliding process, the displacement gear 13 rotates through the meshing with the toothed blocks 16 which are equidistantly distributed on the inner surface of the extending rod 9, the displacement gear 13 rotates to drive the transmission gear 14 to rotate, the transmission gear 14 rotates to drive the detection rod 15 to rotate until the detection rod 15 rotates to a position horizontal to the ice surface, at the moment, the lower end of the sliding rod 12 abuts against the lower end of the extension rod 9 so as not to continuously slide downwards, and then the clamping rod 10 is clamped with the sliding rod 12 under the support of the limiting spring 11, so that the relative position between the sliding rod 12 and the extension rod 9 is fixed;

then as shown in fig. 1-4, researchers receive signals through the wireless signal transmitter 3 and convert the signals into electric signals to control the servo controller 2, the servo controller 2 drives the rotating motor 7 to rotate, the rotating motor 7 drives the extending rod 9 to rotate through the driving gear 8, the extending rod 9 drives the detecting rod 15 to rotate, the detecting rod 15 monitors the thickness of the ice layer through a sensor arranged on the outer surface of the detecting rod 15 in the rotating process, meanwhile, the rotation of the detecting rod 15 also increases the monitoring range of the sensor and enables water around the detecting rod 15 not to freeze in continuous flowing to cause the detecting rod 15 not to rotate, when an electronic sensor on the outer surface of the detecting rod 15 fails due to low temperature, the lifting motor 4 drives the lifting rod 5 to rotate, the lifting rod 5 drives the lifting plate 6 to slide up and down through threaded connection with the lifting plate 6, the lifting plate 6 drives the rotating detecting rod 15 to rotate and sense the ice layer through a mechanical trigger type pressure sensor, when mechanical trigger formula's pressure sensors is blockked and triggers, can reach the ice surface and thickness through calculating the distance of gauge rod 15 and ice surface upper surface to reach and to continue to carry out the purpose monitored to the ice layer under the condition that electronic sensor became invalid, increased holistic practicality.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides a wireless intelligence ice-detecting sensing device, includes removal frame (1), gauge stick (15) and tooth piece (16), its characterized in that: the upper surface of the moving frame (1) is provided with a servo controller (2) and a wireless signal transmitter (3) respectively, the upper surface of the moving frame (1) is provided with a lifting motor (4), the upper end of the lifting motor (4) is connected with a lifting rod (5), the outer surface of the lifting rod (5) is connected with a lifting plate (6), the upper surface of the lifting plate (6) is provided with a rotating motor (7), the lower end of the rotating motor (7) is connected with a driving gear (8), one end of the lifting plate (6) is penetrated by an extending rod (9), the upper surface of the extending rod (9) is connected with a clamping rod (10), a limiting spring (11) is connected between the clamping rod (10) and the extending rod (9), the inner part of the extending rod (9) is connected with a sliding rod (12), and the outer surface of the sliding rod (12) is connected with a displacement gear (13), one end of the displacement gear (13) penetrates through the outer surface of the sliding rod (12), one end, located inside the sliding rod (12), of the displacement gear (13) is connected with a transmission gear (14), the outer surface of the transmission gear (14) is connected with a detection rod (15), and a tooth block (16) is fixed on the inner surface of the stretching rod (9).

2. The wireless intelligent ice-sensing device of claim 1, wherein: the lifting rod (5) is in threaded connection with the lifting plate (6), and the lifting plate (6) and the moving frame (1) form a sliding structure.

3. The wireless intelligent ice-sensing device of claim 1, wherein: the driving gear (8) is connected with the extending rod (9) in a meshed mode, and the driving gear (8) and the lifting plate (6) form a rotating structure.

4. The wireless intelligent ice-sensing device of claim 1, wherein: the clamping rod (10) and the extending rod (9) form a sliding structure, and the clamping rod (10) and the extending rod (9) form an elastic structure through a limiting spring (11).

5. The wireless intelligent ice-sensing device of claim 1, wherein: the sliding rod (12) and the clamping rod (10) form a clamping structure, the sliding rod (12) and the displacement gear (13) form a rotating structure, and the displacement gear (13) is in meshed connection with the transmission gear (14).

6. The wireless intelligent ice-sensing device of claim 1, wherein: the tooth blocks (16) are distributed on the inner surface of the extending rod (9) at equal intervals, and the extending rod (9) is in meshed connection with the displacement gear (13) through the tooth blocks (16).

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