KR101443816B1 - Robust kiosk structure having a temperature maintenance function - Google Patents

Abstract

The present invention relates to a kiosk structure including a kiosk with a thermoelectric semiconductor to maintain a temperature of the kiosk at a predetermined temperature. More particularly, the present invention relates to a kiosk structure including a kiosk, a temperature control pipe, and a thermoelectric semiconductor, wherein a temperature sensor included in the kiosk measures a temperature of the kiosk, and the thermoelectric semiconductor is provided between the kiosk and the temperature control pipe to control a temperature of air introduced through the temperature control pipe. The kiosk according to the present invention may generate a jet stream due to a temperature difference and an atmospheric pressure difference between the introduced air and air inside the kiosk. Accordingly, air may be easily circulated and the jet stream is accelerated using a frame part.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a robust kiosk sculpture having a temperature holding function,

The present invention relates to a kiosk molding capable of maintaining the temperature of the kiosk at a proper temperature through a thermoelectric semiconductor.

More specifically, in a kiosk molding including a kiosk, a temperature control tube and a thermoelectric semiconductor, a temperature sensor provided in the kiosk measures the temperature of the kiosk, and the thermoelectric semiconductor is provided between the kiosk and the temperature control tube, Which can regulate the temperature of the air flowing through the kiosk.

The present invention relates to a kiosk sculpture further including an LCD monitor inside the kiosk, and including a frame portion having a plurality of through holes penetrating the LCD monitor in the direction of the LCD monitor, so that air circulation of the kiosk can be smoothly performed .

The kiosk of the present invention further includes a solar cell cover for receiving solar energy to produce electric power, and relates to a kiosk molding capable of efficiently saving electric power.

The high growth of the national economy and rapid industrialization has brought about a lot of change in people's consciousness and life, and the most prominent of these changes is the field of sightseeing and exploration due to the increase of leisure time.

In addition, the two-day work week, the establishment of a paid vacation system, the promotion of public welfare, the diversification of travel time, the development of traffic, and the increase in leisure time due to changes in the use of transportation means made various external activities possible. To have a hobby.

Thus, a kiosk terminal is used as a way to provide information on the leisure activity area in order to meet the exponentially increasing demand of the national tourism.

Generally, a kiosk is installed in a public place, and not only a tourist guide but also a transportation reservation, a reservation of a lodging company, and a tourist guide are issued to the user, and an unmanned person who provides predetermined information such as road information, weather information, Means a tourist information terminal.

That is, it refers to an unattended terminal installed in a public place so that it can be easily used by the public for unattended automation of information service and business, and is also referred to as a multimedia station or a self service station.

Most of these kiosks use the touch screen method to obtain information or handle purchasing, ticketing, registration, etc. This is accomplished by using external kiosks installed in trails, cultural relics, transportation areas, tourist areas, banks, And the like.

In particular, since the external kiosk is installed outside and has a high space utilization, a variety of sculptures can be additionally mounted.

For example, a kiosk terminal can be additionally installed, and a sculpture on which a bulletin board, a map reminder, an information notice board, and the like are displayed can be additionally provided.

In this case, external kiosk terminals installed in outdoor public facilities such as a mountain trail, a cultural heritage site, a traffic area, a tourist area, or a park are more affected by temperature than an internal kiosk terminal installed in a building.

For example, in the summer, due to the high temperature solar heat, overheating may occur not only in the kiosk itself but also in the LCD monitor installed in the interior of the kiosk, thereby causing a problem of lowering the screen sensitivity of the LCD monitor or generating defective pixels. It causes problems.

In particular, when the LCD monitor is powered on, the temperature is raised only by the operation itself, so temperature management is required intensively.

On the other hand, in winter, the temperature is reduced to below zero, so that the kiosk terminal and the LCD monitor installed therein are cooled, resulting in malfunction due to freezing of the machine.

Therefore, it is urgently required to develop a technology capable of reacting and adapting in real time according to the external temperature, thereby maintaining an appropriate temperature up to the LCD monitor installed in the kiosk as well as the inside of the kiosk.

Regarding the technique for maintaining the proper temperature, a cooling / heating apparatus using a solar cell and a thermoelectric cold / hot device is disclosed in Registration Practical Utility Model No. 20-0223071.

The above-described technology has a structure including a solar cell module, a heat absorbing unit, and a thermoelectric cooler having a heat generating unit. When a room temperature of the automobile is high, the cooling effect by the heat absorbing unit is reduced. And an air conditioner.

However, the above-described technology is advantageous in that the thermoelectric cooler device is directly connected to the solar cell, and the solar device and the thermoelectric cooler device are directly applied to the cooling and heating by connecting with the switch device or the temperature sensor. However, Cooling and heating means are not described.

Also, the method of exchanging air flow according to the thermoelectric cooler device is not described in detail, and thus it is difficult to expect a smooth air circulation.

Next, Patent Publication No. 10-0704143 discloses a heat exchange ventilator for both heating and cooling using a thermoelectric element.

The above-described technique is characterized in that when the temperature sensor senses the temperature of the air, the thermoelectric device reacts by the power regulator, thereby circulating the heating medium through the circulation pipe and the pump, thereby providing cooling and heating and heat exchange ventilation effects .

However, since the above-described technique uses water as a heating medium, there is a disadvantage in that a configuration such as a pump or a circulation pipe is additionally required. In addition, since the air circulation uses an indirect method in which water circulates through a circulation pipe, .

In addition, it is difficult to expect a smooth air circulation effect by a constant air flow exchange method according to a heat exchanger, and it is not possible to utilize the air flow change due to the difference of temperature and air pressure.

Generally, it is required to develop a technology that can control the temperature of the kiosk through the thermoelectric semiconductor, and further includes a temperature sensor for detecting the air inside the kiosk and the temperature of the LCD monitor installed therein, It is required to develop a technique that can spray a direct airflow on the monitor to expect a more efficient cooling and heating effect.

Further, by providing a temperature control tube connected to and connected to the back surface of the kiosk, it is possible to efficiently introduce the outside air into the inside of the kiosk, and also includes a frame inlet and a frame outlet formed by a plurality of through holes, It is urgently required to develop a technology for enabling a smooth air circulation by utilizing the change of the air flow according to the difference of the airflow.

Registration Utility Model Bulletin No. 20-0223071 (Feb. 26, 2001) Patent Registration No. 10-0704143 (Mar. 30, 2007)

The object of the present invention is to provide a kiosk molding including a kiosk, a temperature control tube and a thermoelectric semiconductor, wherein a temperature sensor provided in the kiosk measures a temperature of the kiosk, A semiconductor is provided between a kiosk and a temperature control tube to provide a kiosk fixture capable of controlling the temperature of the air flowing through the temperature control tube.

It is another object of the present invention to provide a kiosk molding structure which further includes an LCD monitor inside the kiosk and includes a frame portion provided with a plurality of through holes penetrating in the direction of the LCD monitor on both sides of the LCD monitor so that air circulation of the kiosk can be smoothly performed. .

Still another object of the present invention is to provide a kiosk molding that can efficiently save power by further including a solar cell cover that receives solar energy to produce electric power.

According to an aspect of the present invention, there is provided a kiosk sculpture comprising: a kiosk for providing information; A temperature control tube 200 installed in the kiosk for sucking outside air and guiding the temperature of the sucked air to the inside of the kiosk; And a thermoelectric semiconductor 300 provided between the kiosk 100 and the temperature control tube 200. In the kiosk molding 1, the kiosk 100 is connected to the inside of the kiosk 100, The air circulation can be smoothly performed as the jet flow is generated due to the temperature difference and the air pressure difference which exist in the air.

The kiosk 100 according to the present invention includes a controller 110 for controlling and setting the kiosk temperature sensor 111 and the LCD temperature sensor 112 and controlling the direction of the electrodes according to temperature to apply a current to the thermoelectric semiconductor 300 ); A suction port 130 connected to the temperature control tube 200 and formed below the kiosk 100 so that air can be introduced into the inside of the kiosk 100; An exhaust port 140 formed with a ventilation fan 141 above the kiosk 100 so that air inside the kiosk 100 can be exhausted; An LCD monitor 150 for displaying schedule information; And a frame unit 160 provided on both sides of the LCD monitor 150. The jet unit 160 accelerates jet flow through the frame unit 160. [

The kiosk molding according to the present invention can control the power applied to the thermoelectric semiconductor according to the measured value of the temperature sensor for measuring the temperature inside the kiosk, and the thermoelectric semiconductor can repeat endothermic reaction or heat generation according to the applied electric power Therefore, it is possible to control the temperature of the air flowing through the temperature control pipe, and the temperature-controlled air is introduced into the inside of the kiosk, thereby having a remarkable effect of controlling the temperature of the kiosk.

According to another aspect of the present invention, a jet flow can be generated through a temperature difference or a pressure difference between air introduced into a kiosk and air present inside a kiosk, and the jet stream is promoted through a frame provided on both sides of the LCD monitor, It has a remarkable effect that air circulation inside the kiosk can be actively performed.

Further, since the power required for driving the kiosk can be produced by itself using the solar cell cover, the present invention has a remarkable effect of reducing power production cost.

1 is a perspective view showing an external configuration of a kiosk molding according to the present invention.
FIG. 2 is a rear view showing the internal construction of the kiosk molding according to the present invention.
3 is a view showing the principle of a thermoelectric semiconductor in a kiosk molding according to the present invention.
4 is a side view of an inner frame portion of a kiosk molding according to the present invention.
5 is a perspective view illustrating an inner frame portion of a kiosk molding according to the present invention.
6 is a cross-sectional view schematically illustrating the action of airflow activation according to Figs. 4 and 5 in a kiosk molding according to the present invention.
7 is a rear view showing another embodiment of the kiosk molding according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor can properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents And variations are possible.

Before describing the present invention with reference to the accompanying drawings, it should be noted that the present invention is not described or specifically described with respect to a known configuration that can be easily added by a person skilled in the art, Let the sound be revealed.

The present invention relates to a kiosk molding capable of maintaining the temperature of a kiosk at a proper temperature through a thermoelectric semiconductor, and more particularly, to a kiosk molding including a kiosk, a temperature control tube and a thermoelectric semiconductor, Wherein the thermoelectric semiconductor is provided between the kiosk and the temperature control tube to control the temperature of the air flowing through the temperature control tube.

The present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view illustrating an external configuration of a kiosk molding according to the present invention, and FIG. 2 is a rear view illustrating an internal configuration of a kiosk molding according to the present invention.

Referring to FIGS. 1 and 2 of the accompanying drawings, a kiosk molding according to the present invention may be constituted by a kiosk 100 and a temperature control tube 200.

The kiosk 100 according to the present invention includes a kiosk temperature sensor 111, an LCD temperature sensor 112, a temperature sensor 114, A controller 120, an air inlet 130, an air outlet 140, an LCD monitor 150, and a frame unit 160.

In this case, the kiosk 100 may have a rectangular shape as shown in the accompanying drawings. Since the scope of the present invention is not limited by the drawings, And may be configured in various forms depending on the region or terrain condition to be installed.

The kiosk 100 may further include a solar cell cover 101.

At this time, the solar cell cover 101 is made of a flexible material and may be configured to cover the outer surface of the kiosk 100 as shown in FIG. 1 of the attached drawings. Depending on the design conditions, the upper surface of the kiosk 100, Or may be formed on one of the side surface, the front surface, and the rear surface.

Further, the kiosk 100 may further include means for displaying other information such as a map display panel on one side. At this time, the solar cell cover 101 may be designed to be formed on one side of another side of the other side.

The solar cell cover 101 can receive solar light, charge the electric power, and store it in the battery 102.

That is, by charging the battery 102 through the solar cell cover 101, power can be efficiently supplied to the devices configured in the kiosk 100.

The kiosk temperature sensor 111 may be provided inside the kiosk 100 and may measure a temperature inside the kiosk 100. [

The LCD temperature sensor 112 may be attached to the LCD monitor 150 and may measure the temperature of the LCD monitor 150 itself.

The kiosk temperature sensor 111 and the LCD temperature sensor 112 may be connected to the controller 120 by a common power line to transmit the measured values of the temperature sensors 111 and 112 to the controller 120, respectively.

The controller 120 can control the direction of the electrode applied to the thermoelectric semiconductor to be described later according to the measured values of the kiosk temperature sensor 111 and the LCD temperature sensor 112 as described above.

Depending on the design conditions, the controller 120 may be further configured on the outer surface of the kiosk 100 in a button or electronic touch manner to set an arbitrary temperature that the user desires to set.

That is, the present invention further includes the thermoelectric element 300 as described above, and this thermoelectric semiconductor 300 will be described below.

The thermoelectric semiconductor 300 may be installed between the kiosk 100 and the temperature control tube 200 as shown in FIG. And the temperature of the outside air flowing through the outdoor unit is converted.

As the element used in the thermoelectric semiconductor 300, a Peltier element can be used, which means a thermoelectric element using the Peltier effect.

Here, the Peltier device is a high-functional electronic device that is mainly used for electronic cooling and can convert heat energy into electric energy or convert electric energy into heat energy.

Such a Peltier element can be constituted by bonding different metals or bonding an N type semiconductor and a P type semiconductor to each other. When a DC current is applied to the thermoelectric element, an endothermic reaction can take place on one side of the thermoelectric element, An exothermic reaction may occur.

Further, the thermoelectric element can be composed of two or more semiconductor couples (P type semiconductor, N type semiconductor) which are electrically in series and thermally parallel, and instead of two kinds of metals, bismuth, tellurium , It is possible to obtain a Peltier element having an efficient heat absorbing and heat generating effect.

It is also a thermal book component that moves heat from the heat absorption surface to the heat dissipation surface. It is possible to change the cooling and heating by reversing the thermoelectric direction. Temperature control of ± 0.05 ℃ is possible by voltage and current control.

Thus, by controlling the current flow, it is possible to easily perform heating as well as cooling, and there is no vibration noise because there is no moving part of the device, and there is no pollution or pollution caused by the freon refrigerant.

The principle of the thermoelectric semiconductor using the Peltier element will be described in detail with reference to Fig.

3 (a) shows a case where the AB plate is a heat absorbing portion and the CD plate is a heat generating portion. As shown in Fig. 3 (a), two kinds of metal ends And current is passed through the anode to the C side and the cathode current to the D side.

When a positive current flows to the C side, the electrons move toward the C plate in the N type semiconductor having a relatively larger number of electrons (-).

At the same time, the cathode current flowing on the D side draws holes toward the D plate due to the nature of the P type semiconductor having a relatively large positive (+).

That is, electrons and holes are collectively coupled to the C-D plate, thereby generating heat.

Here, in order to move (generate) electrons and holes, it is necessary to obtain energy from the outside. Obtaining energy from the outside may mean that the present invention absorbs heat of the air. Thus, Type semiconductor and the P-type semiconductor while absorbing external energy, the AB plate becomes a heat absorbing portion.

On the other hand, the case of FIG. 3 (b) is different.

3 (b) shows a case where the electrode is reversely applied by the electrode application controller 120 according to the present invention. As shown in the figure, a cathode current flows on the C side and a positive current flows on the D side.

Accordingly, electrons are pushed toward the A plate because a large number of electrons already exist in the N type semiconductor.

At the same time, a P-type semiconductor having a large number of holes also pushes holes toward the B plate by an anode current flowing on the D side.

That is, in the case of (b), electrons and holes combine to form an exothermic unit in the AB plate. In the CD plate, an endothermic reaction that absorbs external energy is generated by the movement process of electrons and holes passing through the AB plate.

As a result, the thermoelectric semiconductor 300 has an endothermic function of absorbing heat at one junction according to the direction of current application when electricity is supplied to both junctions of one system in which different metals are bonded, and in the other junction, When the flow of current is reversed, the endothermic and exothermic actions are also reversed.

That is, the direction of the current is determined by the controller 120, and the thermoelectric semiconductor 300 can adjust the temperature of the sucked air by performing an endothermic or exothermic operation as described above.

The suction port 130 may be formed on the lower side of the rear surface of the kiosk 100 and may be formed with a plurality of through holes arranged at predetermined intervals as shown in the drawings.

The inlet 130 is connected to the temperature control tube 200 and functions to allow the temperature controlled thermoelectric semiconductor 300 to flow into the interior of the kiosk 100.

The exhaust port 140 may be formed on the upper surface of the kiosk 100 and may include through holes arranged at predetermined intervals to allow the air to escape.

The exhaust port 140 is provided with a ventilation fan 140 which is sucked through the suction port 130 and allows the air that has been finally cooled or heated by the LCD monitor 150 to be exhausted to the vent hole 140 more smoothly 141 may be provided.

The ventilation fan 141 can be driven by the ventilation fan motor 142.

The LCD monitor 150 is installed inside the kiosk 100 and is attached to the front of the kiosk 100 to display information to be provided on the screen.

For example, it is possible to provide not only a tourist guide but also information such as transportation reservation information, lodging company reservation information, and tourist guide information as well as providing predetermined information such as road information, weather information, and world time information have.

In addition, the LCD monitor 150 may obtain information by applying a touch screen method, handle transactions such as purchase, ticketing, and registration, and may include a glass film and a transparent protective part for protecting the LCD monitor 150 (Not shown) may be provided.

The size and the performance of the LCD monitor 150 may be variously modified by a person skilled in the art and may be freely selected according to the place where the kiosk 100 is installed and the purpose of use.

As shown in FIGS. 4 and 5, the frame unit 160 is provided on both sides of the LCD monitor 150 to fix the LCD monitor 150 more firmly. One frame 161, a frame inlet 162, a second frame 163, and a frame outlet 164.

Particularly, the frame unit 160 can change the air pressure of the air passing through the frame unit 160, so that the difference in relative air pressure between the air introduced from the outside and the air existing inside the frame unit 160 is increased, .

Accordingly, air circulation inside the kiosk 100 can be smoothly and quickly performed.

The frame portion 160 is characterized in that the first frame 161 and the second frame 163 have different thicknesses so that the stopper can be formed.

The barrier rib 165 may be installed on the first frame 161 and the second frame 163 so as to block air flowing unevenly inside the kiosk 100 from the first frame 161 and the second frame 163 .

Further, the LCD monitor 150 may be further provided on the lower side of the inside of the kiosk 100.

The first frame 161 may be located below the frame 160 and may include a frame inlet 162 formed of a plurality of through holes passing through the LCD monitor 150.

4 and 5, the frame inlet 162 may be formed through both walls of the first frame 161 so that the flow of air introduced through the inlet 130 Can be converted while penetrating through the frame inlet (251).

At this time, it is preferable that the first frame 161 is formed by enclosing upper and lower walls so that air can flow only through the frame inlet 162.

The second frame 163 is located at an upper portion of the frame portion 160 and may be configured as a hollow pipe.

The frame outlet 164 is included in the second frame 163 so that the frame outlet 164 can be formed with a plurality of through holes on one wall in the direction of the LCD monitor 150, .

Here, the second frame 163 is preferably formed so that the upper wall is opened and the lower wall is sealed so that the air introduced into the pipe through the frame outlet 164 can flocculate to the exhaust port 140.

That is, the frame portion 160 may be formed as shown in FIGS. 4 and 5, but the scope of the present invention is not limited to or reduced by the drawings, and as described above, Needless to say, various modifications can be made within the technological scope for controlling the flow.

The temperature control tube 200 is connected to the suction port 130 formed on the rear surface of the kiosk 100 so that external air is introduced through the air inlet 201 and the introduced air is guided into the interior of the kiosk 100 And the like.

In addition, a suction fan 210 may be installed inside the temperature control tube 200 so that the air can be sucked into the temperature control tube 200 more quickly and smoothly. In addition, It goes without saying that the fan motor 211 may be further provided.

Hereinafter, referring to FIG. 6, the flow of air generated according to the action of the thermoelectric semiconductor 300 and the structure of the frame portion 160 is as follows.

6 is a cross-sectional view schematically illustrating the action of airflow activation according to Figs. 4 and 5 in a kiosk molding according to the present invention.

As shown in Fig. 6, the flow of air will be described in detail according to the operation sequence of the kiosk molding according to the present invention.

The solar cell cover 101 covering the outside of the kiosk 100 receives sunlight and charges electric power to the battery 102 in real time.

For example, in the summer, the temperature of the LCD monitor 150 and the temperature of the kiosk 100 also increases.

At this time, the temperature is sensed by the kiosk temperature sensor 111 and the LCD temperature sensor 112, and the measured value is transmitted to the controller 120.

The controller 120 sets the direction of the electrode to be applied to the thermoelectric semiconductor 300 and flows the current.

In this case, it is preferable that the plate of the thermoelectric semiconductor 300 provided on the side of the temperature control tube 200 is a heat absorbing part. When the thermoelectric semiconductor 300 operates, the suction fan motor 211 and the blower fan motor 142 (Not shown) drives the suction fan 210 and the ventilation fan 141.

As the suction fan 210 is operated, hot air can be introduced through the air inlet 201 more quickly and smoothly, and hot air is cooled through the heat absorbing plate of the thermoelectric semiconductor 300 .

The cooled air continues to flow through the temperature control tube 200 and flows into the interior of the kiosk 100 through the inlet 130 of the kiosk 100.

The cooling air flowing into the inside can contact the LCD monitor 150 while flowing in a straight line and can be exhausted through the exhaust port 140 and the ventilation fan 141.

The second frame 163 can be introduced in a diagonal direction through the frame intake port 162 of the first frame 161 and collide with the central portion of the LCD monitor 150, The second frame 163 and the second frame 163. The second frame 163 and the second frame 163 are connected to each other.

Such air circulation can generate a jet flow due to the pressure generated by the frame intake port 162 formed of a plurality of through holes and the temperature difference generated while contacting the LCD monitor 150.

The jet stream is originally located at the altitude of about 9 to 10 km above the middle of the mid-latitude region (Kwokyeon-myeon), ② the air flow from the west to the east based on the northern hemisphere, ③ the speed varies from 100 to 200 ④ The path shape of the air current flows like a river or a serpent in the valley. ⑤ The air current is formed in the northern hemisphere at about 35 ° N in winter and around 50 ° N in summer.

However, in the present invention, the jet stream described in the present invention is caused by the heat absorption and heat generating action of the thermoelectric semiconductor 300 and the structure of the frame portion 160 Circulating flow of air.

Accordingly, the process of circulating air can be activated more quickly, and the cooling air can be passed straight through, and the cooling air can stay in the central portion of the LCD monitor 150 for a longer time, The temperature of the monitor 150 can be cooled more efficiently.

When the temperature measured by the kiosk temperature sensor 111 and the LCD temperature sensor 112 reaches a predetermined temperature set in the controller 120 after the lapse of the time, the power is automatically shut off and the controller 120, The operation of the suction fan motor 142 and the suction fan motor 211 can be stopped.

7 is a rear view showing another embodiment of the kiosk molding according to the present invention.

As shown in FIG. 7 of the accompanying drawings, a means such as a spray pipe 400 may be provided to directly spray the converted air to the LCD monitor 150, and the spray pipe 400 may be provided with a suction And is connected to the suction port 130 of the kiosk 100, so that the converted air can be sucked more efficiently.

According to this structure, air can be directly injected into the LCD monitor 150 to induce a proper temperature more effectively. The shape of the injection pipe 400 is not limited to this, Of course.

The kiosk molding according to the present invention configured as described above can control the power applied to the thermoelectric semiconductor according to the measurement value of the temperature sensor for measuring the temperature inside the kiosk. It is possible to control the temperature of air introduced through the temperature control tube and to control the temperature of the kiosk by allowing the temperature controlled air to flow into the inside of the kiosk.

According to another aspect of the present invention, a jet flow can be generated through a temperature difference or a pressure difference between air introduced into a kiosk and air present inside a kiosk, and the jet stream is promoted through a frame provided on both sides of the LCD monitor, So that air circulation inside the kiosk can be actively performed.

In addition, since the power required for driving the kiosk can be produced by itself using the solar cell cover, the power generation cost can be reduced.

1 to 7 have described only the main points of the present invention. As far as various designs can be made within the technical scope of the present invention, the present invention is limited to the configurations of Figs. 1 to 7 Or it is self-evident.

1: kiosk sculpture 100: kiosk
101: solar cell cover 102: battery
111: kiosk temperature sensor 112: LCD temperature sensor
120: controller 130: inlet
140: exhaust port 141: ventilation fan
142: Ventilation fan motor 150: LCD monitor
160: frame part 161: first frame
162: frame inlet 163: second frame
164: frame outlet 165:
200: Temperature control tube 201: Air inlet
210: Suction fan 211: Suction fan motor
300: thermoelectric semiconductor 400: injection pipe

Claims (9)

A kiosk 100 for providing information; And a temperature control tube (200) installed in the kiosk (100) for sucking outside air and controlling the temperature of the sucked air to guide the inside of the kiosk (100) into the kiosk (100)
The kiosk (100)
An LCD monitor 150 for displaying schedule information and a frame unit 160 provided on both sides of the LCD monitor 150,
- smooth air circulation is possible as jet flow is generated due to temperature difference and air pressure difference between the air introduced into the inside of the kiosk (100) and the air inside the kiosk (100)
- facilitating jet flow generated internally through the frame portion (160).
The method according to claim 1,
Further comprising a thermoelectric semiconductor (300) provided between the kiosk (100) and the temperature control tube (200) to adjust the temperature of the air sucked through the temperature control tube (200).
The method of claim 2,
The kiosk (100)
A controller 120 for applying a current to the thermoelectric semiconductor 300 according to measured values of a kiosk temperature sensor 111 for measuring the temperature of the kiosk and an LCD temperature sensor 112 for measuring a temperature of the LCD monitor 150, );
A suction port 130 connected to the temperature control tube 200 and formed below the kiosk 100 to allow air to flow into the inside of the kiosk 100; And
And an air outlet (140) formed on the upper side of the kiosk (100) so that the air inside the kiosk (100) can be exhausted, the vent hole (141) being formed in the upper side of the kiosk (100).
The method of claim 3,
The controller (120)
Wherein a direction of an electrode applied to the thermoelectric semiconductor (300) is made different according to measured values of the kiosk temperature sensor (111) and the LCD temperature sensor (112).
The method according to claim 1,
The kiosk (100)
And a solar cell cover (101) made of a flexible material to receive solar light to charge electric power.
The method according to claim 1,
The temperature control tube (200)
And a suction fan (210) installed inside the kiosk (100) to suck outside air.
The method according to claim 1,
The frame unit 160 includes:
And a second frame (163) provided on both sides of the LCD monitor (150), the first frame (161) and the second frame (163).
The method of claim 7,
The first frame (161)
And a frame inlet (162), which is made up of a plurality of through holes penetrating in the direction of the LCD monitor (150).
The method of claim 7,
The second frame (163)
And a frame outlet port (164) formed in a hollow pipe shape so that the inside air can be agglomerated and discharged to the exhaust port (140)
The frame outlet (164)
And a plurality of through holes formed in one wall of the LCD monitor (150).

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