KR20230068469A - Apparatus for Harvesting Energy by using air pressure and pressure measuring device for same - Google Patents

Abstract

The present invention relates to energy harvesting using air pressure and an air pressure measuring device using the same, which includes an air inlet into which air pressure is introduced from a branch pipe branching from a supply pipe supplying air pressure and supplying branches to each distribution position; a harvesting generating unit disposed inside the air inlet unit and generating a harvesting force by rotation with the introduced air pressure; It is disposed on one side of the air inlet, electromotive force generating unit to generate the rotational force generated in the harvesting generating unit; an exhaust unit disposed on one side of the electromotive force generator and discharging air passing through the electromotive force generator while supporting rotation of the harvesting generator; and a wireless sensing transmitter disposed on one side of the electromotive force generating unit, receives the electromotive force generated by the electromotive force generating unit, measures the position and air pressure of the branch pipe, and transmits the radio signal.

Description

Energy harvesting using air pressure and air pressure measuring device using the same {Apparatus for Harvesting Energy by using air pressure and pressure measuring device for same}

This embodiment relates to energy harvesting using air pressure and an air pressure measuring device using the same.

The contents described below merely provide background information related to the present embodiment and do not constitute prior art.

A device for supplying air pressure by pressurizing air is installed and used in industrial fields such as automobile assembly plants and textile factories.

Such an air pressure supply device is used while branching and supplying air to required locations by connecting a supply pipe from an air generating device.

Accordingly, there is a problem in that the quality of the process is degraded because the air pressure is changed for each branched position according to the distance to the supply device and the connection state of the pipe.

In order to solve this problem, a device that measures the air pressure for each branch pipe position and continuously monitors the measured air pressure value is required to supply air pressure of the same pressure to each branch pipe.

Conventional sensors have problems in that, as power is required, means for supplying power must first be installed for each installed location, increasing costs due to facility expansion and making it difficult to move and install.

In addition, with the recent development of IoT technology, wireless information communication and wireless information communication and There is a demand for a next-generation communication network system that provides wireless power transmission and wireless power charging together.

In addition, in the field of wireless power charging technology, research on a wireless energy harvesting network that performs information communication and wireless power charging at the same time is being conducted.

Accordingly, there is an increasing need for a device capable of moving and installing a plurality of branch pipes for each position and monitoring the air pressure for each position in real time by transmitting a wireless signal.

The object of the present invention, which was created in response to the above-described needs, is to branch and supply pressurized air to a plurality of locations, and to obtain location and air pressure by self-generated power using harvesting technology that converts air pressure into electromotive force. It is possible to move and install by sensing and transmitting wirelessly, and measure air pressure by location in real time with one installation, thereby providing energy harvesting using air pressure that reduces costs and an air pressure measuring device using the same. .

Energy harvesting using air pressure and an air pressure measuring device using the air pressure according to an embodiment of the present invention include an air inlet into which air pressure is introduced from a branch pipe for branching and supplying branched and distributed positions from a supply pipe supplying air pressure; a harvesting generating unit disposed inside the air inlet unit and generating a harvesting force by rotation with the introduced air pressure; an electromotive force generating unit disposed on one side of the air inlet and generating an electromotive force by the rotational force generated in the harvesting generating unit; an exhaust unit disposed on one side of the electromotive force generator and discharging air passing through the electromotive force generator while supporting rotation of the harvesting generator; and a wireless sensing transmitter disposed on one side of the electromotive force generating unit, receives the electromotive force generated by the electromotive force generating unit, measures the position and air pressure of the branch pipe, and transmits the radio signal.

In addition, the air inlet unit, the air inlet body installed at the position where the air having a pneumatic pressure is introduced on the branch pipe; and an air inlet space located inside the air inlet body and in which the harvesting generating unit is installed to allow air to flow in; and a rotation support protrusion protruding to one side from the inner center of the air inlet body and having a rotation support groove in the form of a groove into which the rotation part of the harvesting generator is inserted and supported.

In addition, the harvesting generating unit is disposed inside the air inlet unit, and includes a blade body provided with a plurality of rotating blades at radial positions on an outer circumference so as to generate rotational force by the inflowing air pressure; and a rotating shaft fixed to the center of the blade body and rotatably supported by the exhaust unit via the electromotive force generating unit to rotate the electromotive force generating unit.

In addition, the electromotive force generating unit is disposed on one side of the air inlet, has an electromotive force generating space in which the electromotive force is generated, and has a core housing provided in the form of a core in which the electromotive force is generated by rotation of the magnetic force; and a magnetic rotating body connected to the rotating part of the electromotive force generating unit in a state located in the electromotive force generating space inside the core housing to generate electromotive force by rotation in the core housing in the form of a magnet having magnetic force. there is.

In addition, guide bearings disposed on one side and the other side of the core housing, provided in the form of a pair of bearings so that the rotational portion of the harvesting generator fixed to the magnetic rotational body is rotatably disposed; And a pair of guide bearings are respectively supported, and one side and the other side of the electromotive force generating space are respectively supported in contact with each other to prevent the rotational part of the harvesting generating part from moving left and right, rotationally supported to one side and the other side of the core housing. It may further include; an axis guide body.

In addition, the exhaust unit is disposed on one side of the electromotive force generating unit, the exhaust body having an exhaust space therein through which the air passing through the electromotive force generating unit passes for discharge; an exhaust pipe disposed on one side of the exhaust body and configured to exhaust air pressure in a direction branched and supplied from the branch pipe; and an exhaust bearing in the form of a bearing disposed inside the exhaust body and rotatably supporting the rotating part of the harvesting generator.

In addition, the wireless sensing transmitter is electrically connected to one side of the electromotive force generating unit and converts the generated electromotive force into DC at the DC conversion unit to measure the position and air pressure using the power stored in the energy storage unit. sensor to do; and a wireless module that converts the measurement value sensed by the sensor into a wireless signal and transmits it to the outside.

As described above, according to the present embodiment, in branching and supplying pressurized air to a plurality of positions, the position and air pressure are generated by self-generated power using a harvesting technology that converts air pressure into electromotive force. It is possible to move installation by sensing and transmitting wirelessly, and it provides an effect of reducing costs as it is possible to measure air pressure by location in real time with one installation.

1 is a configuration diagram showing a state in which energy harvesting using air pressure and an air pressure measuring device using the same according to an embodiment are installed.
Figure 2 is a perspective view showing the energy harvesting using the air pressure of Figure 1 and the air pressure measuring device using the same.
Figure 3 is an exploded perspective view showing the energy harvesting using the air pressure of Figure 1 and the air pressure measuring device using the same.
Figure 4 is a cross-sectional view showing the energy harvesting using the air pressure of Figure 1 and the air pressure measuring device using the same.
FIG. 5 is a cross-sectional view of the energy harvesting using the air pressure of FIG. 5 and the air pressure measuring device using the same from another direction in which parts are omitted.
6 is a process diagram showing a wireless sensing transmitter, which is a main component of energy harvesting using air pressure and an air pressure measuring device using the air pressure of FIG. 1 .

Hereinafter, this embodiment will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram showing a state in which energy harvesting using air pressure and an air pressure measuring device using the same according to an embodiment are installed.

Referring to FIG. 1 , energy harvesting using air pressure and an air pressure measuring device using air pressure according to an embodiment of the present invention are branch pipes branching from a supply pipe 10 supplying air by applying pressure to a position where air pressure is used. It is installed in (20) and in measuring the air pressure branched and supplied for each location and position of the branch pipe, it is possible to receive the measured value remotely by wireless communication while supplying power by harvesting using air pressure.

Such energy harvesting using air pressure and an air pressure measuring device using the same include a harvesting device 100 and a wireless sensing transmitter 200.

2 is a perspective view showing energy harvesting using air pressure and an air pressure measuring device using the same of FIG. 1, FIG. 3 is an exploded perspective view showing energy harvesting using air pressure and an air pressure measuring device using the same of FIG. 1, and FIG. 1 is a cross-sectional view showing energy harvesting using air pressure and an air pressure measuring device using the same, and FIG. 5 is a cross-sectional view showing energy harvesting using air pressure and an air pressure measuring device using the same in another direction with parts omitted.

Referring to Figures 2 to 5, the harvesting device 100 is provided to generate electromotive force by using the air pressure that is installed and supplied to each of the plurality of branch pipe 20 positions.

Such a harvesting device 100 includes an air inlet 110, a harvesting generating unit 120, an electromotive force generating unit 130, and an exhaust unit 140.

The air inlet 110 is provided so that air pressure is introduced from the branch pipe 20 branched from the supply pipe 10 for supplying air pressure and branched and supplied for each distribution position.

The air inlet 110 includes an air inlet body 111, an air inlet space 112, and a rotation support protrusion 113.

The air inlet body 111 is installed on the branch pipe 20 at a position where air having air pressure is introduced.

The air inlet space 112 is located inside the air inlet body 111 and the harvesting generator 120 is installed so that air is introduced.

The air inlet body 111 is connected to the branch pipe 20 and is provided with air pressure to provide power for generating rotational force in the harvesting generator 120 located in the air inlet space 112 while passing the branched air pressure. do.

The rotation support protrusion 113 protrudes to one side from the inner center of the air inlet body 111 and is provided to have a rotation support groove 114 in the form of a groove into which the rotation part of the harvesting generating unit 120 is inserted and supported.

The harvesting generating unit 120 is disposed inside the air inlet body 111 and is provided to generate harvesting force by rotation with the introduced air pressure.

The harvesting generating unit 120 includes a blade body 122 and a rotational shaft 123.

The blade body 122 is disposed inside the air inlet space 112, and is provided with a plurality of rotary blades 121 radially positioned on the outer circumference so as to generate rotational force by the incoming air pressure.

The rotating shaft 123 is fixed to the center of the blade body 122 and is rotatably supported by the exhaust unit 140 via the electromotive force generating unit 130 to rotate the electromotive force generating unit 130 .

That is, the rotary blade 121 on the outer circumference of the blade body 122 generates rotational force while being in direct contact with the supplied air pressure. It is provided to rotate.

In other words, the blade body 122 provided with the rotary blade 121 generates rotational force while being rotated by the supplied air pressure, and generates electromotive force by rotating the electromotive force generator 130 with the generated rotational force to generate electromotive force. provides the power to generate

The electromotive force generator 130 is disposed on one side of the air inlet body 111 and is provided to generate electromotive force by rotational force generated from the blade body 122 .

The electromotive force generator 130 includes a core housing 131, a magnetic rotation body 133, a guide bearing 134, and an axis guide body 135.

The core housing 131 is disposed on one side of the air inlet body 111, has an electromotive force generation space 132 in which electromotive force is generated, and is provided in the form of a core in which electromotive force is generated by rotation of magnetic force.

That is, the core housing 131 may be provided in the form of a core around which a coil that generates electromotive force by rotational movement of magnetic force inwardly is wound.

The magnetic rotating body 133 is connected to the rotating shaft 123 in a state located in the electromotive force generating space 132 and is provided to generate electromotive force by rotation in the core housing 131 in the form of a magnet having magnetic force.

The guide bearings 134 are disposed on one side and the other side of the core housing 131, respectively, and are provided in the form of a pair of bearings so that a rotating shaft fixed to the magnetic rotating body 133 is rotatably disposed.

The shaft guide body 135 supports a pair of guide bearings 134, respectively, and one side of the electromotive force generating space 132 is prevented from moving left and right by the rotation shaft supported by rotation to one side and the other side of the core housing 131. It is provided so as to be supported in contact with the other side, respectively.

That is, in the pair of shaft guide bodies 135, a guide bearing 134 into which the rotation shaft 123 is rotatably inserted is installed in the center, and is supported to prevent flow while contacting the electromotive force generating space 132 in a cross shape. It is provided to minimize the loss of rotational force according to.

The exhaust unit 140 is disposed on one side of the core housing 131 and is provided to discharge air passing through the electromotive force generation space 132 while supporting rotation of the rotation shaft 123 .

The exhaust unit 140 includes an exhaust body 141 and an exhaust pipe 143 .

The exhaust body 141 is disposed on one side of the core housing 131, and is provided to have an exhaust space 142 through which air passing through the electromotive force generation space 132 passes for discharge.

The exhaust pipe 143 is disposed on one side of the exhaust body 141 and is provided to exhaust air pressure in a direction branched from the branch pipe 20 and supplied.

6 is a process diagram showing a wireless sensing transmitter, which is a main component of energy harvesting using air pressure and an air pressure measuring device using the air pressure of FIG. 1 .

Referring to FIG. 6 , the wireless sensing transmitter 200 is disposed on one side of the electromotive force generator 130, receives the electromotive force generated by the electromotive force generator 130, and receives the position of the branch pipe 20 and the air pressure. It is provided to measure and transmit as a radio signal.

Such a wireless sensing transmitter 200 includes a sensor 203 and a wireless module 204 .

The sensor 203 is electrically connected to one side of the core housing 131 and converts the generated electromotive force to DC in the DC conversion unit 201 and uses the power stored in the energy storage unit 202 to determine the location and location. Sensing to measure air pressure.

The sensor 203 is provided to transmit a position sensing signal for sensing the position of the plurality of branch pipes 20 and an air pressure sensing signal for sensing the air pressure supplied from the branch pipe 20 to the wireless module 204. do.

The wireless module 204 converts the measurement value sensed by the sensor 203 into a wireless signal and transmits it to the outside.

That is, the wireless module 204 converts the position sensing signal and the air pressure sensing signal sensed by the sensor 203 into wireless signals and transmits them wirelessly by the electromotive force generated by the electromotive force generator 130 .

The above description is merely an example of the technical idea of the present embodiment, and various modifications and variations can be made to those skilled in the art without departing from the essential characteristics of the present embodiment. Therefore, the present embodiments are not intended to limit the technical idea of the present embodiment, but to explain, and the scope of the technical idea of the present embodiment is not limited by these embodiments. The scope of protection of this embodiment should be construed according to the claims below, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of rights of this embodiment.

10: supply pipe 20: branch pipe
100: harvesting device 110: air inlet
111: air inlet body 112: air inlet space
113: rotation support protrusion 114: rotation support groove
120: harvesting generating unit 121: rotary blade
122: blade body 123: rotational shaft
130: electromotive force generating unit 131: core housing
132: electromotive force generation space 133: magnetic rotating body
134: guide bearing 135: shaft guide body
140: exhaust unit 141: exhaust body
142: exhaust space 143: exhaust pipe
200: wireless sensing transmission unit 201: DC conversion unit
202: energy storage unit 203: sensor
204: wireless module

Claims (7)

an air inlet into which air pressure is introduced from a branch pipe branching from a supply pipe supplying air pressure and supplying branches to each distribution location;
a harvesting generating unit disposed inside the air inlet unit and generating a harvesting force by rotation with the introduced air pressure;
an electromotive force generating unit disposed on one side of the air inlet and generating an electromotive force by the rotational force generated in the harvesting generating unit;
an exhaust unit disposed on one side of the electromotive force generator and discharging air passing through the electromotive force generator while supporting rotation of the harvesting generator; and
A wireless sensing transmitter disposed on one side of the electromotive force generator and receiving the electromotive force generated by the electromotive force generator to measure the position and air pressure of the branch pipe and transmit the radio signal.
Energy harvesting using air pressure and air pressure measuring device using the same.
According to claim 1,
The air inlet,
an air inlet body installed at a position where air having pneumatic pressure is introduced onto the branch pipe; and
An air inlet space located inside the air inlet body and in which the harvesting generating unit is installed to allow air to flow in; and
A rotation support protrusion protruding to one side from the inner center of the air inlet body and having a rotation support groove in the form of a groove into which the rotating part of the harvesting generator is inserted and supported.
Energy harvesting using air pressure and air pressure measuring device using the same.
According to claim 1,
The harvesting generating unit,
a blade body disposed inside the air inlet and provided with a plurality of rotary blades on an outer circumference at radial positions so as to generate rotational force by air pressure introduced therein; and
A rotating shaft fixed to the center of the blade body and rotatably supported by the exhaust unit via the electromotive force generating unit to rotate the electromotive force generating unit;
Energy harvesting using air pressure and air pressure measuring device using the same.
According to claim 1,
The electromotive force generator,
a core housing disposed on one side of the air inlet, having an electromotive force generation space therein, and having a core shape in which electromotive force is generated by rotation of magnetic force; and
In a state located in the electromotive force generating space inside the core housing, a magnetic rotating body that is connected to the rotating part of the electromotive force generating unit to generate electromotive force by rotation in the core housing in the form of a magnet having magnetic force;
Energy harvesting using air pressure and air pressure measuring device using the same.
According to claim 4,
Guide bearings disposed on one side and the other side of the core housing and provided in the form of a pair of bearings so that the rotational portion of the harvesting generator fixed to the magnetic rotational body is rotatably disposed; and
Each of the pair of guide bearings is supported, and one side and the other side of the electromotive force generating space are supported in contact with each other to prevent the rotational part of the harvesting generator supported by rotation to one side and the other side of the core housing from moving left and right. Axial guide body; further comprising
Energy harvesting using air pressure and air pressure measuring device using the same.
According to claim 1,
the exhaust,
an exhaust body disposed on one side of the electromotive force generator and having an exhaust space therein through which air passing through the electromotive force generator is discharged; and
An exhaust pipe disposed on one side of the exhaust body and provided to exhaust air pressure in a direction branched from the branch pipe and supplied thereto.
Energy harvesting using air pressure and air pressure measuring device using the same.
According to claim 1,
The wireless sensing transmitter,
a sensor that is electrically connected to one side of the electromotive force generating unit and converts the generated electromotive force into DC at the DC conversion unit and senses the position and air pressure using the stored power in the energy storage unit; and
A wireless module that converts the measured value sensed by the sensor into a wireless signal and transmits it to the outside;
Energy harvesting using air pressure and air pressure measuring device using the same.

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