KR20120011559A - Cooling devices in parasol - Google Patents

Abstract

PURPOSE: A cooling device for parasol is provided to increase cooling efficiency by extending contacting hour of external air with a cooling part, supply cooled air without loss, control cooled air, and automatically operate in accordance with surrounding temperature. CONSTITUTION: A cooling device for parasol comprises: a blasting tool(17) which blows external air from the top of a supporting stand(3); a cooling part which heat-absorbs and cools air blown from outside; a heat transfer tool(13) having a radiating unit which releases absorbed heat; a duct having an emission tube which transfers the frozen air and releases transferred cool air; an exhausting part which guides redundancy cool air to the radiating unit and discharges heat dissipation; the supporting stand which has the exhausting part; and a controller(18) which controls an air blasting tool and heat transferring tool.

Description

Cooling device for parasols {COOLING DEVICES IN PARASOL}

The present invention relates to a cooling device for a parasol that can efficiently supply cooled air to a user using the parasol.

In general, parasols only had the ability to block the sun's direct sunlight and ultraviolet rays. Until now, the patented technology related to the above-mentioned purpose of parasol mainly focuses on improving the structural convenience of flesh in the process of folding and unfolding the parasol, and the structure that can easily change the angle of the parasol in conjunction with the change of the incident angle of sunlight over time. It is coming true.

Recently, a number of patents related to the technology considering the cooling function in addition to the above functions in consideration of the portable characteristics of the parasols have been applied for, and in the prior art, Korean Patent Publication No. 10-2002-0075437 ( Publication date: 29 November 2002).

In the related art, the amount of cold air generated inside the awning is dependent on the temperature difference generated according to the power applied to the thermoelectric element and the amount of heat dissipated in the heat dissipation part. Lack of applicable mechanisms makes the heat dissipation mechanism dependent primarily on natural convection. Therefore, if the convection flow outside the awning stream is not sufficient, there is a disadvantage that the amount of cold air generated inside is not sufficient to achieve the original purpose. In particular, when excessive power is supplied by the photovoltaic cell in the absence of a forcible heat radiating means in the heat radiating portion, there is a concern that damage to the thermoelectric element due to overload.

In addition, even if a certain amount of cold air is generated inside the awning stream due to the proper air condition (wind convection), the cooling part of the thermoelectric element is located at the top of the parasol, so there is a considerable distance to reach the user. Due to the loss of the strength of the cold air due to the loss (mixing) with the surrounding hot air (Mixing) there is a disadvantage that it is difficult to deliver a sufficient level of cold air satisfactory to the user.

The present invention has been proposed to solve the above-mentioned conventional problems, and an object of the present invention is to provide a cooling device for a parasol that can be supplied to the parasol user by cooling the external air.

Still another object of the present invention is to provide a cooling device for a parasol capable of supplying clean cold air to a user by cooling external air from which foreign substances have been removed.

Still another object of the present invention is to provide a cooling device for a parasol in which the cooling efficiency can be increased by extending the time that external air contacts the cooling unit.

Still another object of the present invention is to provide a cooling device for a parasol that can supply cooled air to a user without loss.

Still another object of the present invention is to provide a cooling device for a parasol capable of controlling the direction of cold air provided to a user.

Still another object of the present invention is to provide a cooling device for a parasol that operates automatically according to the surrounding climate.

Another object of the present invention is to provide a cooling device for a parasol that can prevent the damage of the thermoelectric element due to overload by making a sufficient heat dissipation (dissipation) in the heat dissipation portion of the thermoelectric element during the cold air production of the thermoelectric element.

In order to achieve the above object, the present invention provides a heat exchange means having a blowing means for blowing outside air, a cooling unit for absorbing and cooling the blown outside air, and a heat dissipating unit for radiating heat absorbed heat, and cooled air. And a support having a duct section having a discharge pipe for transporting and discharging the transferred cold air, a support having a discharge section for guiding the remaining excess cool air to the heat dissipation unit and dissipating heat radiation from the heat dissipation unit, and a control unit for controlling the blowing means and the heat exchange unit. do.

The blowing means includes a blower installed at an upper portion of the support to blow external air, a net installed at one end of the blower, and a fan for transferring the blown outside air to the cooling unit.

The blowing means further includes a cap for preventing the inflow of rain water in the rain.

And a duct portion is inserted into the support so that a flow path is formed between the outside of the duct portion and the inside of the support.

And a swirl generating device and a tumble flow device for increasing the contact time between the air blown by the blowing means and the cooling unit.

The swirl growth value includes a swirl tube provided between the blowing means and the cooling unit, and a plurality of air blades formed to be inclined at regular intervals on the inner surface of the swirl tube.

The tumble flow apparatus is composed of a plurality of fins inclined in a cooling unit and installed in multiple stages, a fin hole formed at a lower portion of the fin, through which air passes, and a plurality of pins formed on an upper surface of the fin. It includes.

The heat exchange means includes a thermoelectric element.

The heat dissipation part further includes a flow path narrowing as the space between the heat dissipation part and the support rises from the bottom up.

It includes forming a heat insulating material on the outer surface of the duct portion.

The duct unit further includes a discharge hole which is formed in the lower portion of the duct unit and the excess cool air is discharged to the support.

The apparatus may further include a mixing unit installed between the cooling unit and the discharge tube to mix the air cooled by the cooling unit with the air transferred without being greatly influenced by the cooling unit.

It further comprises a discharge control means for controlling the direction of the cold air discharged from the discharge tube.

The emission control means includes a control tube covering the discharge tube and a control hole formed in the control tube to coincide with the discharge tube.

The control unit includes a sensor for sensing an external climate to operate the blowing means and the heat exchange means.

The sensor includes a temperature sensor or an illuminance sensor.

The present invention configured as described above allows the user to continuously receive cool cold air regardless of the outdoor air condition so that the cooling effect that can be enjoyed only outdoors indoors where power supply is always available in the poor outdoor activities of heat waves during the summer season There is an advantage to enjoying.

The present invention has the advantage of supplying clean cold air to the user by cooling the outside air is removed foreign matter.

The present invention has the advantage that the cooling efficiency can be increased by extending the time the outside air is in contact with the cooling unit.

The present invention has the advantage that the cooled air can be supplied to the user without loss.

The present invention has the advantage of controlling the direction of the cold air provided to the user.

The present invention has the advantage of automatically operating in accordance with the surrounding climate.

The present invention has the advantage that sufficient heat dissipation (dissipation) is made in the heat dissipation portion of the thermoelectric element during the cold air production process of the thermoelectric element can prevent damage to the thermoelectric element due to overload.

1 is a perspective view showing a parasol to which an embodiment of the present invention is applied.
Figure 2 is a view showing a blowing means for blowing outside air applied to the present invention.
Figure 3 is a view showing the flow of air to move the swirl generating device, tumble flow apparatus and duct applied to the present invention.
Figure 4 is a block diagram showing a state in which a tumble flow apparatus applied to the present invention is installed.
Figure 5 is a perspective view showing the discharge portion applied to the present invention.
Figure 6 is a perspective view showing a heat sink of the heat exchange means applied to the present invention.
7 is a perspective view showing a cap of the blowing means applied to the present invention.
8 is a perspective view showing a tumble flow apparatus applied to the present invention.

When described in detail with reference to the accompanying drawings in order to fully understand the present invention.

As shown in FIG. 1, the embodiment of the present invention is applied to a parasol including a sunshade cloth 2 covered by a plurality of ribs 1 and a support 3 supporting a plurality of ribs 1, and a support 3. A heat exchange means (13) having a blowing means (17) for blowing outside air from the upper part of the upper part), a cooling part (41) for absorbing and cooling the blown outside air, and a heat dissipation part (42) for radiating the absorbed heat; A duct part 24 having a discharge pipe 15 for transporting the cooled air and releasing the transferred cold air, and guides the remaining excess cool air to the heat dissipation unit 42 to discharge the heat radiation of the heat dissipation unit 42. And a control unit 18 for controlling the blower means 17 and the heat exchange means 13.

Shading cloth (2) is installed on top of the rib (1) to sunshine or rain water. And, the rods (1) are radially expanded to be installed to be folded or unfolded on top of the support (3).

The support (3) is in the shape of a tube, the upper end of the blowing means 17 is installed, the lower end is fixed to the handle or fixed to the ground is installed. Accordingly, the support 3 can be carried by the user by holding the handle, or can be used by being fixed to the ground using a fixing part.

At this time, the support 3 is formed with a discharge portion 16, so as to be located on the side of the top of the support (3) to be located on the outer side of the awning cloth (2) of the high temperature absorbing heat radiated during the heat exchange process Do not mix the air again with the outside air of the user side.

As shown in Figure 2, the blowing means 17 is a blower pipe 22 is installed on the upper portion of the support (3), a net 21 is installed at one end of the blower pipe 22 to prevent the inflow of foreign matter, and the blower pipe ( 22 is provided inside the fan 23 to blow the outside air to the blower tube (22). That is, the outside air blown into the blower pipe 22 through the net 21 by the driving of the fan 23 is transferred to the duct part 24.

At this time, the blower pipe 22 has a wide upper portion and a lower portion is formed in a narrow shape so that when the outside air is transferred from the duct portion 24, the blown air is concentrated in the duct portion 24 is quickly transferred.

In addition, the blower pipe 22 is provided with a cap 25 to cover the net 21 to prevent the failure of the equipment through the inflow of rain water in the rain.

Here, the cap 25 has a through hole 27 formed in the lower portion, the lower end of the cap 25 is formed with a female thread, the male thread is formed on the outside of the blower tube 22, the cap 25 is a blower tube 22 ) Is combined.

3 and 4, the heat exchange means 13 is preferably a thermoelectric element. Here, the cooling part 41 of the heat exchange means 13 is exposed inside the duct part 24, and the heat dissipation part 42 is installed so that it may be exposed to the outside of the duct part 24. As shown in FIG. At this time, the heat radiation portion 42 is formed with a plurality of fins or plates to increase the contact area of the air.

Therefore, air is cooled by the cooling part 41 exposed inside the duct part 24, and it is conveyed along the duct part 24. As shown in FIG.

At this time, the swirl generating device 14 is fixedly installed inside the duct part 24 so as to be positioned between the cooling part 41 and the blowing means 17.

The swirl generating device 14 is installed between the blowing means 17 and the cooling unit 41 such that the outer surface of the swirl tube 45 is in close contact with the inner surface of the duct unit 24.

In addition, the inner surface of the swirl pipe 45 is composed of a plurality of air blades 46 are formed to be inclined spaced apart at regular intervals.

That is, the air conveyed from the blower pipe 22 is supplied to the cooling unit 41 while being spirally rotated by the air blade 46, and the rotated air increases the area and time of contact with the cooling unit 41 to facilitate cooling. Is done.

The tumble flow apparatus 50 is used as another means for increasing the contact area and time in the cooling part 41 of the air blown.

The tumble flow apparatus 50 has a structure in which a plurality of fins 51 formed at an acute angle in a direction opposite to the advancing direction of the air blown through the cooling unit 41 are coupled to the surface of the cooling unit 41. 휜 hole 52 formed to pass the cooled air to the lower part of the) and the upper surface of the fin 51 to the air from the cooling unit 41 by increasing the contact area with the air and improving the heat transfer coefficient due to convective flow Consists of a plurality of pins 53 to facilitate the transfer of cold air.

In addition, the plurality of fins 51 formed in the cooling unit 41 are formed in the cooling unit 41 toward the central axis of the duct 24 as it descends from the upper portion to the lower portion of the cooling unit 41. It is formed in a multi-stage structure in which the length of. At this time, the air blown into the space formed between the fan 51 and the cooling unit 41 causes a tumble flow to increase the contact time of the blown air with the cooling unit 41.

In addition, a mixing unit 55 is formed between the cooling unit 41 and the discharge tube 15 to mix the air conveyed and the air cooled by the cooling unit 41 without being greatly influenced by the cooling unit 41. do.

The mixing part 55 is fixed to the inside of the duct part 24 in a hemispherical shape with a plurality of support members (not shown) and is installed so that the round side faces upward.

Duct portion 24 is formed in the form of a square or round tube, it is preferably inserted into the inside of the support 3, the duct 24 and the support 3 is preferably a dual structure. Blowing means 17 is installed at the upper end of the duct part 24, the discharge pipe 15 is formed in the middle to discharge the cold air, the lower end of the discharged cold air and the support ( 3) The discharge hole 31 is formed to discharge between the inside.

In addition, the rectangular duct 24 has four corners are supported on the inner side of the support 3 so that the outer surface of the duct 24 is maintained at a predetermined distance from the inner side of the support 3.

At this time, the heat exchange means 13 is preferably installed on two or four symmetrical surfaces of the rectangular duct portion 24, respectively.

In addition, when the duct part 24 is a circular pipe, a separate space keeping member (not shown) is used so that the outside of the duct part 24 is maintained at a constant distance inside the support.

It is preferable that the air discharged between the duct part 24 and the support 3 forms a narrow flow path in order to cause strong turbulent flow in the heat radiating part 42 so that the discharge rate of the air is increased.

In addition, it is preferable that a heat insulating material is formed on the outside of the duct part 24 so that cold air inside the duct part 24 is not conducted to the outside.

Both ends of the discharge pipe 15 is connected to the inside of the duct portion 24 and the outside of the support 3 to discharge the cooled air to the outside, it is preferable that two or more discharge pipes 15 are formed in different directions. Do.

At this time, the release control means 34 is installed outside the support 3 to control the opening and closing of the discharge pipe to control the discharge direction of the cooled air.

As shown in FIG. 5, the emission control means 34 includes a control tube 35 covering the discharge tube 15 and a control hole 36 formed in the control tube 35.

Here, the control tube 35 covers the discharge tube 15 in the state inserted into the outside of the support (3). Therefore, when the user rotates the control tube 35 to the left or the right and matches the control hole 36 and any of the discharge pipe 15, the cold air through the matched control hole 36 and the discharge pipe 15 Will be discharged.

At this time, it is preferable that the jaw supporting the rotation of the control tube 35 is formed in the support 3 at the lower portion of the discharge tube 15.

In addition, when the release control means 34 are not used, the release control means 34 is released from the discharge tube 15 to be fixed to the support 3.

At this time, a male screw thread is formed on the inner side of the discharge pipe 15 and on the outer side of the female thread and the support 3.

In addition, the male thread acid is preferably formed on the upper part of the discharge pipe 15.

That is, when the emission control means 34 are not used, the emission control means 34 is coupled to the thread formed on the upper part of the discharge tube 15 so that the emission control means 34 is spaced apart from the discharge tube 15. do.

The remaining cool air discharged through the discharge pipe 15 is discharged to the discharge hole 31 formed in the lower portion of the duct part 24 to radiate heat along the flow path formed between the duct part 24 and the support 3. Guided to 42 is formed to discharge the heat radiation of the heat radiation portion to the discharge portion (16).

Here, it is preferable that two or more discharge holes 31 are formed in different directions.

The control unit 18 is for operating the blowing means 17 and the heat exchange means 13, it may be implemented as a controller with a built-in MCU. At this time, the control unit 18 is configured to include a switch for turning on / off the blower 17 and the heat exchange means 13 and a temperature sensor or an illuminance sensor for automatically operating by sensing the climate.

At this time, the temperature sensor or illuminance sensor is preferably installed on the outside of the sunshade (2).

That is, the temperature sensor measures the outdoor temperature and provides the measured temperature value to the controller 18, and the illuminance sensor detects the outdoor light and provides the detected value to the controller 18.

Here, the control unit 18 is driven by a power supply unit (not shown) for supplying power. At this time, the power supply is preferably a battery or solar cell (11).

In addition, the photovoltaic cell 11 may be any one of a light and flexible dye-sensitized solar cell, a CIGS solar cell, an organic solar cell, and the like. As described above, the parasol composed of the light solar cell 11 is light and easy to move, and the parasol composed of the flexible solar cell 11 has the advantage that the solar cell 11 is not damaged when folded. .

In addition, the photovoltaic cell 11 is preferably installed on the outer surface of the chayangcheon (2) while positioned between the ribs (1).

That is, when folding the parasol, the photovoltaic cell 11 positioned between the ribs 1 does not interfere with the ribs 1 and does not break.

The operation of the cooling device for a parasol according to the present invention having the above configuration will be briefly described with reference to the drawings.

The user measures the state of the external climate with the temperature sensor or the illuminance sensor while the switch of the control unit 18 is turned on, and transmits the measured value to the control unit 18, and when the measured value exceeds the set temperature value or illuminance value, the blowing means And heat exchange means 13 are operated.

At this time, when the blowing means 17 received power from the power supply unit starts operation, the outside air filtered by the foreign matter is blown into the blowing pipe 22 through the mesh 21 installed at one end of the blowing pipe 22.

In addition, since rain can flow into the blower pipe 22 during rain, the cap 25 is placed on the mesh 21 so that the outside of the blower pipe 22 and the inside of the cap 25 are fixed with a thread of a male and female structure. At this time, the outside air flows into the blower pipe 22 through the through hole 27 formed in the cap 25.

The outside air blown by the blower pipe 22 is transferred to the duct part 24 by the driving of the fan 23 provided inside the blower pipe 22. At this time, the blower pipe is formed in a funnel structure, when the outside air is transferred from the duct portion 24, the blown air is rapidly transferred while concentrated in the duct portion (24).

The conveyed air is passed through the swirl generating device 14 installed between the blower 17 and the cooling unit 41 to generate a swirl flow, and also to the tumble flow apparatus 50 formed in the cooling unit 41. Due to the tumble (tumble) flow is formed is slowly passed through the cooling unit (41).

That is, the fin 51 of the tumble flow apparatus 50, which is formed in multiple stages by passing the swirl generator 14 and having swirl flow, is formed at an acute angle in the direction opposite to the flow of air to the cooling unit 41. The tumble flow causes the tumble flow to move along the fan 51. The tumble flows through the fan hole 52 formed in the lower part of the fan 51 after being cooled by the cooling unit 41 connected to the lower part of the fan 51. Move to 51 (51) of.

In this way, the air is in contact with the cooling unit 41 for a long time by the swirl generator 14 and the tumble flow apparatus 50 is sufficiently cooled to be transferred to the lower end of the duct 24.

At this time, the air is conveyed without being greatly influenced by the cooling unit 41 near the center of the duct 24 by the mixing unit 55 formed between the cooling unit 41 and the discharge pipe 15. Uniform air is transferred to the duct part 24 by mixing the air cooled by the air and the cooling part 41.

The conveyed air is discharged through the discharge pipe 15 to the user, it is preferable that a plurality of discharge pipe 15 is formed to face different directions for a plurality of users.

Here, the direction of the cold air discharged may be controlled using the control hole 36 of the discharge control means 34 installed outside the discharge pipe 15.

That is, when the cooled air is discharged in various directions through the plurality of discharge tubes 15, the control unit 36 and the plurality of control holes 36 are rotated by rotating the discharge control means 34 covering the discharge tube 15 to the left or the right. When one of the discharge pipes 15 is matched, the cooled air is discharged to the outside through the corresponding discharge pipe 15 and the control hole 36.

When the emission control means 34 is not used, the air cooled in various directions is discharged through the plurality of discharge pipes 15 when the discharge control means 34 is positioned at a predetermined interval apart from the discharge pipe 15.

At this time, the release control means 34 is fixed to the outside of the support 3 by a male thread formed on the outside of the support 3 and a female thread formed on the inside of the release control means 34.

Excess cool air remaining in the duct part 24 without being discharged through the discharge pipe 15 is disposed between the support 3 and the duct part 24 through a discharge hole 31 formed in the lower part of the duct part 24. To the flow path.

Here, the excess cool air discharged to the discharge hole 31 is guided to the heat radiating portion 42 through the flow path to promote convective heat transfer. That is, the excess cool air passes through the heat dissipation unit 42 of the thermoelectric element to discharge the heat of the heat dissipation unit 42 through the discharge unit 16.

At this time, by forming a narrow flow path between the heat dissipation plate 43 and the support part 3 installed in the heat dissipation unit 42, a strong turbulent flow is caused by the increase in speed, so that the heat dissipation is more efficiently performed.

Although embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features thereof. You can see that well. Therefore, the above-described embodiments are to be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the following claims rather than the foregoing description, and the meaning and scope of the claims and their equivalents. All changes or modifications derived from the concept shall be construed as being included in the scope of the present invention.

11: solar cell
13 heat exchange means
14: Swirl generator
15: discharge tube
16: discharge part
17: blowing means
18: control unit

Claims (16)

Blowing means for blowing outside air;
Heat exchange means having a cooling unit for absorbing and cooling the blown outside air, and a heat dissipating unit for radiating heat absorbed heat;
A duct portion having a discharge tube for transferring cooled air and releasing the transferred cold air;
A support having a discharge part for discharging the radiated heat of the heat dissipation part by guiding the discharged remaining cool air to the heat dissipation part;
A control unit controlling the blowing means and the heat exchange means;
Cooling device for a parasol comprising a. The method of claim 1,
The blowing means is
A blower pipe installed in the upper part of the support to blow external air;
Nets installed at one end of the air duct,
Cooling device for a parasol, characterized in that composed of a fan for transferring the outside air to the cooling unit to be blown. The method of claim 2,
The blowing means is a parasol cooling device further comprises a cap for preventing the inflow of rain in the rain. The method of claim 1,
Cooling device for a parasol characterized in that the duct is inserted into the support so that the flow path is formed between the outside of the duct and the inside of the support. The method of claim 1,
And a swirl generating device and a tumble flow device for increasing the contact time between the air blown by the blowing means and the cooling unit. 6. The method of claim 5,
The swirl growth value
A swirl tube provided between the blowing means and the cooling unit;
Cooling device for a parasol, characterized in that consisting of a plurality of air blades are formed inclined spaced apart at a predetermined interval on the inner surface of the swirl pipe. 6. The method of claim 5,
The tumble flow apparatus is
A plurality of fins inclined to the cooling unit and installed in multiple stages,
A fin hole formed in the lower part of the fin and through which air passes;
Cooling device for a parasol comprising a plurality of pins (pin) formed on the upper surface of the fin (fin). The method of claim 1,
The heat exchange means
Cooling device for a parasol, characterized in that the thermoelectric element. The method of claim 1,
The heat dissipation unit
Cooling device for a parasol characterized in that it further comprises a flow path narrowing as the space between the heat radiating portion and the support from the bottom up. The method of claim 1,
Cooling device for a parasol, characterized in that to form a heat insulating material on the outer surface of the duct. The method of claim 1,
The duct section
Cooling device for the parasol is formed in the lower portion of the duct is formed discharge hole for exhausting the excess cool air to the support. The method of claim 1,
And a mixing unit installed between the cooling unit and the discharge tube to mix the air conveyed without being greatly influenced by the cooling unit and the air cooled by the cooling unit. The method of claim 1,
Cooling device for a parasol further comprising a discharge control means for controlling the direction of the cold air discharged from the discharge tube. The method of claim 13,
The release control means
A control tube covering the discharge tube,
Cooling device for a parasol comprising a control hole formed in the control tube to match the discharge tube. The method of claim 1,
The control unit is a cooling device for a parasol comprising a sensor for sensing the external climate to operate the blowing means and the heat exchange means. 16. The method of claim 15,
The sensor is a cooling device for a parasol, characterized in that the temperature sensor or the illuminance sensor.

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