TWM459179U - Fastening control system of atmosphere probing balloon - Google Patents

Description

Mooring control system for air balloon

The novel creation system relates to a mooring control system for detecting air balls, in particular, the use of the height of the air detecting ball and the setting of the user to control the winding and lengthening of the air ball tether.

In recent years, due to air pollution problems, global climate change has occurred, and natural disasters have continued, highlighting the importance of atmospheric environmental pollution detection and natural disaster monitoring.

There is a meteorological radiometer below the tethered balloon, so the pressure, altitude, temperature and humidity data of the atmosphere can be measured during the ascending and descending of the captive balloon, and the personal control can be controlled regularly on different cable heights. The motor and the sampling bag are simultaneously sampled by the small motor at different heights after the captive balloon is raised to the final height. When the sampling is completed, the descending captive balloon is taken off the sampling bag, and immediately at the sampling point is O ₃ , NOx, SO ₂ , NMHC, CO and other continuous monitors for the concentration analysis of various pollutants.

At present, the mooring control device for the air ball is unable to accurately maintain the balloon at a predetermined lift height when the wind speed is changed, and the exact position of the sample cannot be accurately determined afterwards.

In order to improve the shortcomings of the mooring control system of the air balloon, the present invention provides a mooring control system for the air balloon, which is provided with at least: a box body, a winding drum, a tether, and a first system. A rope eye fixing arm, a second tether hole moving mechanism, a motor and a rotational speed tension controller.

Wherein the winding drum is coupled to the casing and driven by a motor for winding the system Rope, control the lift height and recovery of the air balloon.

The first tether eye fixing arm is fixed to the box body, and the first tether hole is arranged at the upper end thereof, so that the lengthening and retracting of the tether must pass through the fixed point of the top of the tethering control system to facilitate sounding. Lifting and recycling of the balloon, and avoiding the tether winding the box itself or sweeping other surrounding objects when the wind direction suddenly changes.

The second tether aperture moving mechanism is provided with a second tether aperture for guiding the tether to move back and forth, so that the tether is compacted and wound on the winding drum layer by layer.

The speed tension controller is electrically connected to the motor, and the motor adjusts the tether according to the height comparison result returned by the air balloon, so that the air balloon is maintained at a height required for monitoring, continues to lift off, lowers the height, and pulls back. ground

1‧‧‧Tethered control system

11‧‧‧ cabinet

12‧‧‧ winding drum

13‧‧‧ tether

14‧‧‧Exploring the air ball

15‧‧‧First tether eye fixing arm

16‧‧‧Second tether hole moving mechanism

17‧‧‧Motor

18‧‧‧Speed tension controller

20‧‧‧ Cover

141‧‧‧GPS device

142‧‧‧RF device

143‧‧‧Electronic altimeter

151‧‧‧First tether eyelet

161‧‧‧Second tether eyelet

162‧‧‧Rolling shaft with double helix guide groove

163‧‧‧Slide

164‧‧‧Transmission mechanism

201‧‧‧through long trough

202‧‧‧ openings

203‧‧‧Transparent window

Fig. 1 is a schematic view showing an application of a tethered control system for exploring a air ball to control the application of a tether of an air ball.

Fig. 2 is a perspective view showing an embodiment of a mooring control system for a creative air balloon.

Figure 3 is a perspective view showing the mooring control system of the air balloon of the creation, using the second tether eye on the slider to guide the movement of the tether.

Figure 4 is a perspective view showing the embodiment of the mooring control system of a creative air balloon with a cover.

As shown in FIG. 1 to FIG. 3 , an embodiment of the mooring control system 1 for creating a air balloon is provided with at least one box 11 , a winding drum 12 , a tether 13 , and a first A tether eyelet fixing arm 15, a second tether eyelet moving mechanism 16, a motor 17, and a rotational speed tension controller 18.

The box body 11 can be any metal product, and the gravity of the box body is used to resist the traction of the air ball and stay on the ground. A wheel set can be arranged at the bottom for carrying, and a handle can be provided on the side for convenient lifting. The wheel set can be selected from industrial grade load-bearing casters and wheel sets containing brake mechanism, so that the operator can easily move it to the operation site and fix it to quickly complete the installation of the monitoring station.

The winding drum 12 can be axially connected to the inside or the outside of the casing 11, and can be directly driven by the motor 17, or indirectly driven by the reduction gear set to wind the tether 13, and control the lift height of the air balloon 14 and the winding recovery.

The first tether eyelet fixing arm 15 is fixed to the casing 11 for testing, and the upper end is provided with a first tether eyelet 151, so that the lengthening and retraction of the tether 13 must pass through the fixed point of the top of the tethering control system 1, In order to observe, and to prevent the tether 13 from suddenly changing in the wind direction, the casing 11 itself is wound or swept to other surrounding objects.

The second tether eyelet moving mechanism 16 is provided with a second tether eyelet 161 for guiding the tether 13 to move back and forth, so that the tether 13 is compacted and wound on the winding drum 12 layer by layer. Both the first tether eye 151 and the second tether eye 161 may be made of a ceramic or Teflon-coated metal article to provide wear and smoothness and to avoid abrasion of the tether 13.

The second tether hole moving mechanism 16 of the embodiment includes a rotating shaft 162 provided with a double spiral guiding groove, and the second tether hole 161 is just moved to move the width of a tether 13 when the winding drum 12 makes one rotation. . In addition, the second tether aperture moving mechanism 16 also includes a slider 163 that is guided by the rotating shaft 162 provided with the double spiral guiding groove. The second tether eye 161 of the present embodiment is fixed to the sliding seat 163, and can automatically continue to move backwards when the second tether eye 161 reaches the end of the stroke.

The rotating shaft 162 provided with the double spiral guiding groove can be driven by the driving mechanism 164 and the winding roller 12, or can be driven by the motor 17 through a transmission mechanism 164; the rotating shaft 162 provided with the double spiral guiding groove rotates once At this time, the slider 163 just guides the second tether eyelet 161 to move the width of a tether 13, whereby the tether 13 is compacted and wound on the winding drum 12 layer by layer.

The speed tension controller 18 is electrically connected to the motor 17, and the control motor 17 adjusts the tether 13 according to the height comparison result returned by the air balloon 14, so that the air balloon 14 is maintained at a height required for monitoring, and continues to lift off. Lower the height and pull back to the ground. The speed tension controller 18 may include a proportional-integral-derivative controller (PID) that inputs the lift height from a computer or an attached input device and dynamically compares the height of the air balloon 14 to output a pulse to the motor 17. The variable voltage is controlled to control the forward rotation, the reverse rotation, the acceleration, the deceleration of the motor 17, and the torque output of the motor 17 are regulated.

To detect the height of the air balloon 14, as shown in FIG. 1, the air balloon 14 carries a GPS device 141 or an electronic altimeter 143 and a radio frequency device 142, and the GPS device 141 or electronic altimeter is used by the radio frequency device 142. The measured height value is passed back to the ground so that the rotational speed controller 18 can drive the motor 17 in comparison with the height value and the operator's command to cause the winding drum 12 to lengthen, secure or rewind the tether 13.

Preferably, as shown in FIG. 4, in order to protect the operator, the laundry or foreign matter is prevented from being accidentally caught in the casing 11, or the foreign matter in the casing 11 is caused to fly out with the winding drum 12 in the hoisting, A cover 20 may be added to the top of the casing 11. Preferably, the cover 20 is provided with a long slot 201 extending therethrough for substantially the corresponding range of movement of the second tether eye 161 for the tether 13 to pass therethrough. The through slot 201 can be closed or extend to the side of the cover 20 to form an opening 202 for the operator to cover or remove the cover 20 along the length of the slot 201 without being tied at all. The rope 13 is blocked.

In addition, the cover 20 of the embodiment may also be provided with a transparent window 203 for observing the working condition of the winding drum 12 in the casing 11 at any time during the hoisting process.

In summary, the mooring control system of the air balloon of the present invention can control the lengthening and rewinding of the tether 13 by the height value of the air balloon 14 returned by the GPS device 141 or the electronic altimeter 143 and the radio frequency device 142. In order to automatically maintain the lift height, and after the cover 20 is covered, the winding of the winding drum 12 can be observed through the transparent window, or the cover 20 can be removed without being caught by the tether, which should be practical. Patent requirements such as sex, novelty and progress.

1‧‧‧Tethered control system

11‧‧‧ cabinet

13‧‧‧ tether

15‧‧‧First tether eye fixing arm

17‧‧‧Motor

18‧‧‧Speed tension controller

20‧‧‧ Cover

151‧‧‧First tether eyelet

164‧‧‧Transmission mechanism

201‧‧‧through long trough

202‧‧‧ openings

203‧‧‧Transparent window

Claims (10)

A mooring control system for detecting air balls, comprising at least: a box body resting on the ground by gravity; a winding drum connected to the box body; a tether connected to one air ball at one end and connected to the other end at the other end In the winding drum; a first tether eye fixing arm, one end is fixed to the box body, and the other end is provided with a first tether eyelet for guiding the tether through the lengthening and rewinding thereof, a top end of the mooring control system of the air balloon; a second tether aperture moving mechanism provided with a second tether eye for guiding the linear movement of the tether relative to the winding drum to make the tether compact And a layer-by-layer form is wound on the winding drum; a motor is fixed to the box for driving the winding drum; and a rotational speed tension controller drives the motor according to the height data returned by the air balloon. Controlling the forward and reverse rotation and stopping of the motor to adjust the lengthening and retracting of the tether, so that the air balloon can be maintained at a height required for monitoring according to an operator's command, and continues to lift and lower the height. And pull back to the ground and other operations. The mooring control system for the air balloon according to claim 1, further comprising a cover, wherein the cover is disposed substantially in a range corresponding to the movement of the second tether eye, and is provided with a through The long slot allows the tether to pass therethrough. The mooring control system for an air balloon according to claim 2, wherein the through slot opening is provided on one side of the cover so that an operator can remove the length along the length of the slot The cover is completely blocked by the tether. The mooring control system for an air balloon according to claim 2, wherein the cover is provided with a transparent window for observing the winding condition of the winding drum. The mooring control system for the air balloon according to claim 1, wherein the air is detected. The ball system carries a GPS device and a radio frequency device, and the radio device is used to transmit the height value measured by the GPS device to the ground, so that the speed tension controller can compare the height value measured by the GPS device with the operator's command. Thereby driving the motor to allow the winding drum to lengthen, secure or rewind the tether. The mooring control system for an air balloon according to claim 1, wherein the air ball system carries an electronic altimeter and a radio frequency device, and the radio frequency device is used to transmit the height value measured by the electronic altimeter. The ground causes the speed tension controller to compare the height value measured by the electronic altimeter with the operator's command to drive the motor to lengthen, secure or rewind the tether. The mooring control system for the air balloon according to claim 1, wherein the second tether hole moving mechanism comprises a rotating shaft provided with a double spiral guiding groove, which is exactly when the winding roller rotates one turn. The second tether aperture is guided to move a tether width. The mooring control system of the air balloon according to claim 7, wherein the second tether hole moving mechanism comprises a sliding seat combined with the rotating shaft provided with the double spiral guiding groove, and the sliding seat is The second tether aperture is disposed thereon, and the carriage guides the second tether aperture to move a tether width each time the rotation shaft provided with the double spiral guiding groove rotates one turn. The mooring control system of the air balloon according to claim 7, wherein the shaft provided with the double spiral guiding groove is coupled to the winding drum through a transmission mechanism. The mooring control system for an air balloon according to claim 7, wherein the shaft provided with the double helix guide groove is driven by the motor through a transmission mechanism.