KR102247310B1 - Composite heat dissipation structure and smart structure including the same - Google Patents

Abstract

The present invention relates to a composite heat dissipation structure and a smart structure including the same, in which the smart structure includes: a pole formed vertically from a ground, and configured to mount various electronic devices; an enclosure formed on the pole, and configured to accommodate and protect one electronic device among a lighting device, a CCTV, a display, and a control device; a housing formed inside the enclosure, and configured to accommodate a circuit part of the electronic device; a constant temperature unit formed inside the housing, and configured to constantly control a temperature inside the housing; a constant humidity unit formed inside the housing, and configured to constantly control a humidity remaining inside the housing; a drain unit formed inside the housing, and configured to collect condensed water generated by a temperature difference and discharge the condensed water to an outside; and an environment sensor formed on an outer surface of the pole, and configured to collect external environment information to determine an operation of the constant temperature unit and the constant humidity unit. Accordingly, an environment for allowing an electronic device to operate normally is created.

Description

Composite heat dissipation structure and smart structure including the same}

The present invention relates to a composite heat dissipation structure and a smart structure including the same, and more particularly, a composite heat dissipation structure that allows various electronic devices that are mounted on a pole and perform functions to be maintained in a constant state without being affected by the external environment. And it relates to a smart structure including the same.

In general, streetlights refer to lighting facilities installed along streets for safety and security of street traffic, and types suitable for them are used depending on the places where they are installed, such as highways, general roads, sidewalks, and residential areas.

At this time, for crime prevention, a security CCTV for photographing vehicles or people is formed at the top of the streetlight, and for crime prevention, the surrounding situation is continuously recorded for 24 hours and transmitted to a remote location.

In order to drive such an electronic device, electricity is essentially used, and there is a problem in that the heat generated while the electricity is used affects the circuit, shortening the lifespan or causing a malfunction, requiring frequent maintenance.

In addition, in the case of summer, an electronic device does not operate normally due to an increase in humidity as well as an increase in internal temperature due to direct sunlight.

Korean Patent Publication No. 10-2011-0012017

An object of the present invention for solving the above problems is to provide a complex heat dissipation structure that creates an environment so that the electronic device operates normally by maintaining a constant temperature and humidity inside the enclosure in which the electronic device is formed, and a smart structure including the same. .

In addition, another object of the present invention is to provide a complex heat dissipation structure capable of preventing malfunction due to condensed water and a smart structure including the same by collecting condensed water when it is generated inside the enclosure and discharging it to the outside.

Another object of the present invention is to provide a complex heat dissipation structure capable of cooling or heating, humidifying or dehumidifying without mounting a separate additional device, and a smart structure including the same.

The composite heat dissipation structure of the present invention for solving the above problem includes a housing formed to accommodate and protect electronic devices therein, a housing formed inside the housing and formed to accommodate circuit parts of various electronic devices, A constant temperature unit formed inside the housing and formed to constantly control the temperature inside the housing, a humidity unit formed inside the housing and formed to consistently control the humidity remaining inside the housing; And a drain unit formed inside the housing and collecting condensed water generated by a temperature difference and discharging it to the outside.

In addition, the thermoelectric unit of the composite heat dissipation structure of the present invention is formed inside the housing, and when power is supplied, one side is radiated and the other side is formed to absorb heat, and heat is diffused by being formed on one side and the other side of the thermoelectric element respectively. A heat sink that increases the area to be formed; a heat pipe embedded in the heat sink formed on one surface of the thermoelectric element and disposed in a zigzag shape to radiate heat or absorb heat with the heat sink, and connect to one end and the other end of the heat pipe, respectively A constant temperature pipe that forms a circulation loop and absorbs or radiates heat from the housing and the housing using the fluid flowing therein, and a circulation motor that is formed inside the constant temperature pipe and circulates the refrigerant flowing inside the constant temperature pipe. It characterized in that it is made.

In addition, the heat pipe of the composite heat dissipation structure of the present invention is formed of a copper material, and the heat sink is formed of an aluminum material to prevent cracking or cracking due to thermal expansion.

In addition, the humidity control unit of the composite heat dissipation structure of the present invention dehumidifies the inside of the housing when the internal humidity of the housing is higher than a set value, and humidifies the inside of the housing when the humidity inside the housing is lower than a set value to keep the humidity constant. It is characterized by maintaining.

In addition, the drain unit of the composite heat dissipation structure of the present invention is formed to be inclined toward one side of the housing from the lower surface of the constant temperature unit to collect condensate falling from the constant temperature unit, and to be discharged to the outside when a certain amount of the condensed water is collected. It is characterized in that it is formed.

The smart structure including the composite heat dissipation structure of the present invention is formed vertically from the ground and is formed to be equipped with various electronic devices, and the pole is formed on the pole, and one of a lighting device, a CCTV, a display, and a control device An enclosure formed to accommodate and protect electronic devices therein, a housing formed inside the enclosure and formed to accommodate a circuit portion of an electronic device, and a housing formed inside the housing to maintain a constant temperature inside the housing. A constant temperature unit formed to be controlled, a humidity unit formed inside the housing and formed to constantly control the humidity remaining inside the housing, and condensed water formed inside the housing and generated due to a temperature difference. And a drain unit that collects and discharges it to the outside, and an environmental sensor formed on the outer surface of the pole to collect external environmental information to determine the operation of the constant temperature unit and the humidity control unit.

As described above, according to the complex heat dissipation structure according to the present invention and the smart structure including the same, there is an effect of creating an environment so that the electronic device operates normally by maintaining a constant temperature and humidity inside the enclosure in which the electronic device is formed.

In addition, according to the composite heat dissipation structure and the smart structure including the same according to the present invention, when condensed water is generated inside the enclosure, it is collected and discharged to the outside, thereby preventing a malfunction due to the condensed water.

In addition, according to the composite heat dissipation structure and the smart structure including the same according to the present invention, there is an effect that cooling or heating, humidification or dehumidification is possible without installing a separate additional device.

1 is a view showing a structure for cooling the interior of a case of a composite heat dissipation structure and a smart structure including the same according to the present invention.
Figure 2 is a view showing a detailed structure of the thermostatic unit of the composite heat dissipation structure and the smart structure including the same according to the present invention.
3 is a view showing an electronic device mounted on a pole of a composite heat dissipation structure and a smart structure including the same according to the present invention.

Specific features and advantages of the present invention will be described in detail below with reference to the accompanying drawings. Prior to this, when it is determined that a detailed description of functions and configurations related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description will be omitted.

The present invention relates to a composite heat dissipation structure and a smart structure including the same, and more particularly, a composite heat dissipation structure that allows various electronic devices that are mounted on a pole and perform functions to be maintained in a constant state without being affected by the external environment. And it relates to a smart structure including the same.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a structure for cooling the interior of the case of a composite heat dissipation structure and a smart structure including the same according to the present invention, and FIG. 2 is a detailed structure of a thermostat unit of a composite heat dissipation structure and a smart structure including the same 3 is a view showing a composite heat dissipation structure according to the present invention and an electronic device mounted on a pole of a smart structure including the same.

As shown in FIGS. 1 to 3, the composite heat dissipation structure according to the present invention includes a housing 100 formed to receive and protect electronic devices therein, and is formed inside the housing 100 and includes The housing 200 is formed to accommodate the circuit unit, the thermostatic unit 300 formed in the housing 200 and formed to constantly control the temperature inside the housing 200, and the housing 200 A humidity-humidity unit 400 formed inside and formed to constantly control the humidity remaining inside the housing 200, and a humidity unit 400 formed inside the housing 200 and collecting condensate generated by a temperature difference and discharging it to the outside. It characterized in that it comprises a drain unit (500).

The enclosure 100 is for accommodating and protecting various electronic devices, and protecting the exterior of various electronic devices, that is, a lighting device, a CCTV 610, a display 620, and a control device 630, which are applied as examples in the present invention. It means the outer frame for.

The housing 200 is formed inside the enclosure 100 to seal a place where a circuit unit for driving various electronic devices is formed to isolate and protect it from the external environment. It is preferable that a space in which the constant temperature unit 300, the humidity unit 400, and the drain unit 500 can be mounted is formed therein.

The constant temperature unit 300 is used to maintain a constant temperature inside the housing 200 and the inside of the enclosure 100, and is formed to circulate the refrigerant and control the temperature inside the housing 200 and the enclosure 100 Has been.

At this time, the constant temperature unit 300 is formed in the housing 200, and when power is supplied, a thermoelectric element 340 is formed so that one surface is radiated and the other surface absorbs heat, and is formed on one surface and the other surface of the thermoelectric element 340. The heat sink 330 that increases the diffused area and the heat pipe embedded in the heat sink 330 formed on one surface of the thermoelectric element 340 and disposed in a zigzag shape to radiate heat or absorb heat to the heat sink 330 (320) and a constant temperature pipe that is connected to one end and the other end of the heat pipe (320) to form a circulation loop, and absorbs or radiates heat from the inside of the housing (200) and the housing (100) by using the fluid flowing therein. 310) and a circulation motor 350 formed in the constant temperature pipe 310 to circulate the refrigerant flowing in the constant temperature pipe 310.

When power is supplied, one side of the thermoelectric element 340 is heat-dissipated and heated, and the other side is cooled while absorbing heat, so that one side and the other side can have different temperatures. By using the temperature difference between both sides of the thermoelectric element 340, the housing 200 ) And the inside of the enclosure 100 can be heated or cooled.

At this time, it is preferable that heat sinks 330 are formed on both sides of the thermoelectric element 340 so that heat can be rapidly diffused by increasing the contact area when absorbing or dissipating heat from one side and the other side of the thermoelectric element 340 .

In addition, it is preferable that thermal grease is applied to the surface where the thermoelectric element 340 and the heat sink 330 are in contact with each other to facilitate heat transfer, and the heat sink 330 formed on one surface of the thermoelectric element 340 is the housing 200 A heat dissipation fan (not shown) for discharging air toward the outside of the enclosure 100 is formed after protruding to the outside of the enclosure 100 so that the temperature difference between one side to be radiated and the other side to be absorbed is kept constant.

At this time, a heat dissipation fan is attached to the upper surface of the heat sink 330 formed on one surface of the thermoelectric element 340 so that the heat inside the enclosure 100 is discharged to the outside of the enclosure 100 while the air comes into contact with the heat sink 330 As a result, heat radiated from the thermoelectric element 340 is transferred to air to be cooled.

A hole is formed in the heat sink 330 formed on the other surface of the thermoelectric element 340 so that the heat pipe 320 can be formed therein, and the heat pipe 320 is buried in the heat sink 330. In contact with 330, heat can be transferred.

At this time, the heat pipe 320 is formed of a copper material, and the heat sink 330 is formed of an aluminum material to prevent cracking or cracking due to thermal expansion.

The heat pipe 320 is made of a copper material having a high coefficient of thermal expansion, so that heat can be transferred quickly, but it can be damaged while repeating expansion and contraction by heat, so that the heat sink 330 is formed of aluminum so that the heat pipe 320 is When expanding and contracting, the heat pipe 320 is constrained and fixed.

Through this, the heat pipe 320 is confined to the inside of the heat sink 330 made of aluminum so that expansion is limited, so that damage or uniformity can be prevented by excessive contraction and expansion occurring during heat transfer.

The constant temperature pipe 310 is formed to allow the fluid flowing therein to circulate inside the housing 200 and the housing 100, and one end and the other end of the constant temperature pipe 310 are one end of the heat pipe 320, respectively. And is inserted into the other end to form one circulation loop.

At this time, the constant temperature pipe 310 absorbs heat generated inside the housing 200 and the inside of the housing 100 to lower the temperature, or by supplying heat to the inside of the housing 200 and the inside of the housing 100 to increase the temperature. It is formed to maintain a constant temperature inside the 200 and the housing 100.

A refrigerant flows inside the constant temperature pipe 310 so as to absorb heat or dissipate heat, and the refrigerant may be made of a material that is easy to change in phase at a low temperature, or may be made of a material that transfers heat in a gaseous state without a phase change.

At this time, inside the housing 200, a circulation motor 350 is formed to forcibly circulate the fluid flowing in the constant temperature pipe 310, and the circulation motor 350 sets the fluid flowing inside the constant temperature pipe 310. While rotating in the direction, it is possible to absorb heat inside the housing 200 and the housing 100 or dissipate the heat absorbed.

For example, when cooling the inside of the housing 200 and the housing 100 is high, one side of the thermoelectric element 340 radiates heat to release heat to the outside of the housing 200, and the other side is cooled while absorbing heat to form heat formed on the other side. The sink 330 is in a cooled state.

As the heat sink 330 is cooled, the heat pipe 320 embedded in the heat sink 330 is also cooled, and the fluid transferred from the constant temperature pipe 310 by the circulation motor 350 is the heat pipe 320 As it flows into the furnace, it cools and the temperature decreases.

In this state, when returning to the constant temperature pipe 310 and circulating inside the housing 200 and the housing 100, the heat inside the housing 200 and the housing 100 is transferred to the fluid because the temperature of the fluid is low. The temperature of the fluid is increased to flow back into the housing 200.

The fluid whose temperature has increased is introduced into the heat pipe 320 again, and the heat is absorbed by the thermoelectric element 340 and cooled. Then, the temperature inside the housing 200 and the enclosure 100 is reduced by repeating a series of processes again. You will be able to.

In addition, when the voltage is reversely supplied to the thermoelectric element 340, the other surface of the thermoelectric element 340 on which the heat pipe 320 is formed is heated while being radiated, so that heat can be transferred to the fluid, and the heated fluid is the constant temperature pipe 310 Through this, it is possible to increase the internal temperature by circulating the inside of the housing 200 and the housing 100 and dissipating heat.

In addition, a plurality of thermoelectric elements 340, heat sinks 330, and heating pipes may be formed inside the enclosure 100, and through this, the fluid circulating the constant temperature pipe 310 may dissipate heat from the interior of the enclosure 100. When radiating or absorbing heat, heat transfer may be better.

In addition, when the humidity inside the housing 200 is higher than the set value, the humidity unit 400 dehumidifies the inside of the housing 200, and when the humidity inside the housing 200 is lower than the set value, the humidity inside the housing 200 is humidified. It is characterized in that to keep the constant.

A circuit unit for driving various electronic devices is formed inside the housing 200, and since the circuit unit is vulnerable to humidity, there is a need to keep the humidity inside the housing 200 constant.

To this end, the housing 200 is formed in a sealed state, and a humidity control unit 400 is formed on one side of the housing 200 to control the humidity inside the housing 200.

At this time, the humidity control unit 400 is able to remove moisture remaining in the air inside the housing 200 by using a desiccant or a Peltier method, and the inside of the housing 200 is dried in a direction opposite to the direction of operation through a reverse voltage. In this case, it is possible to prevent whitening of electronic components by supplying moisture to the inside of the housing 200 while operating in reverse.

The drain unit 500 is formed to be inclined toward one side of the housing 200 from the lower surface of the constant temperature unit 300 to collect condensate falling from the constant temperature unit 300, and is formed to be discharged to the outside when a certain amount of condensed water is collected. It is characterized by being.

The drain unit 500 is for removing condensed water generated due to low temperature inside the housing 200, and condensed water around the circulation motor 350, heat sink 330, and heat pipe 320 of the constant temperature unit 300 It is equipped with a number of ramps on the lower surface so that it can be collected.

The drain unit 500 has a discharge path on the other side of the lower part of the housing 200, and the condensed water generated due to the temperature decrease of the constant temperature unit 300 is moved to the discharge path to be discharged.

At this time, since the discharge path is formed in an N-shape, it is desirable to prevent the condensate from entering the middle and external air from flowing through the discharge path.

In addition, the smart structure including the composite heat dissipation structure according to the present invention is formed vertically from the ground and is formed in a pole 600 formed so that various electronic devices can be mounted, and a lighting device, CCTV 610 ), the display 620, the control device 630, the housing 100 formed to accommodate and protect any one of the electronic devices therein, and is formed inside the housing 100, and the circuit part of the electronic device is accommodated. The housing 200 is formed so as to be formed, the constant temperature unit 300 is formed inside the housing 200 and is formed to constantly control the temperature inside the housing 200, and is formed inside the housing 200. A humidity control unit 400 formed to constantly control the humidity remaining inside the housing 200, and a drain unit 500 formed inside the housing 200 and collecting condensed water generated by a temperature difference and discharging it to the outside. ), and an environmental sensor 640 formed on the outer surface of the pole 600 to collect external environmental information and determine the operation of the constant temperature unit 300 and the humidity unit 400.

The pole 600 is formed vertically from the ground and is used to support various electronic devices to be mounted, and the bottom surface is fixed so as not to fall due to close contact with the ground, and the upper surface protrudes from both sides to irradiate the street with lights. Or, it is formed to be able to photograph surrounding images through the CCTV 610 for crime prevention.

In addition, an advertisement display 620 is formed in the center of the pole 600 so that various visual information can be provided to the people traveling the distance, and a control device 630 is provided at the bottom of the pole 600 to enable external power and communication. Is provided to transmit power and control signals to various electronic devices mounted on the pole 600.

The enclosure 100 refers to an external frame of the lighting device, CCTV 610, display 620, and control device 630 formed on the pole 600, and a housing 200, a constant temperature unit inside each electronic device Since 300, the humidity control unit 400, and the drain unit 500 are respectively formed, it is possible to maintain the electronic device in a constant temperature and humidity state.

In addition, a plurality of environmental sensors 640 are formed on the outer surface of the pole 600 so that the constant temperature unit 300 and the humidity unit 400 can be actively operated according to the external environment, and the environmental sensor 640 Since the temperature and humidity can be measured, the operation of the constant temperature unit 300 and the humidity unit 400 can be controlled based on the measured information.

As described above, according to the complex heat dissipation structure according to the present invention and the smart structure including the same, it is possible to create an environment so that the electronic device operates normally by maintaining a constant temperature and humidity inside the enclosure in which the electronic device is formed. When condensed water is generated inside, it is collected and discharged to the outside to prevent malfunction due to condensed water, and cooling, heating, humidification or dehumidification is possible without installing a separate additional device.

As described above, the present invention has been described with a focus on preferred embodiments, but a person having ordinary knowledge in the technical field to which the present invention pertains may vary the present invention within the scope not departing from the technical spirit and scope described in the claims of the present invention. It can be modified or modified accordingly. Accordingly, the scope of the invention should be construed by the claims set forth to include examples of such many variations.

100: housing 200: housing
300: constant temperature unit 310: constant temperature pipe
320: heat pipe 330: heat sink
340: thermoelectric element 350: circulation motor
400: humidity unit 500: drain unit
600: pole 610: CCTV
620: display 630: control device
640: environmental sensor

Claims (6)

A housing formed to accommodate and protect electronic devices therein;
A housing formed inside the housing and formed to accommodate circuit units of various electronic devices;
A constant temperature unit formed inside the housing and configured to constantly control a temperature inside the housing;
A humidity control unit formed inside the housing and configured to constantly control humidity remaining inside the housing;
Includes; a drain unit formed inside the housing and collecting condensed water generated by a temperature difference and discharging it to the outside,
The constant temperature unit is
A thermoelectric element formed inside the housing and configured to radiate heat on one side and absorb heat on the other side when power is supplied;
A heat sink formed on one surface and the other surface of the thermoelectric element to increase an area through which heat is diffused and formed of an aluminum material;
Consisting of
Since the heat sink and the heat pipe are formed of different materials, the heat pipe is confined to the inside of the heat sink to limit expansion, thereby preventing damage or cracking due to contraction and expansion due to heat transfer
The humidity control unit removes moisture remaining in the air inside the housing and operates in reverse through a reverse voltage to supply moisture inside the housing,
The drain unit is characterized in that the drain unit has an N-shaped discharge path formed under the housing, so that the discharged condensate is formed so that external air does not flow in.
Composite heat dissipation structure.
The method of claim 1,
The constant temperature unit is
A constant temperature pipe connected to one end and the other end of the heat pipe to form a circulation loop and absorb or radiate heat from the housing and the housing by using a fluid flowing therein;
A circulation motor formed inside the constant temperature pipe to circulate the refrigerant flowing inside the constant temperature pipe; characterized in that it further comprises
Composite heat dissipation structure.
delete The method of claim 1,
The humidity control unit is
When the internal humidity of the housing is higher than a set value, the inside of the housing is dehumidified, and when the humidity inside the housing is lower than a set value, the inside of the housing is humidified to maintain a constant humidity.
Composite heat dissipation structure.

The method of claim 1,
The drain unit is formed to be inclined toward one side of the housing from a lower surface of the constant temperature unit to collect condensed water falling from the constant temperature unit, and is formed to be discharged to the outside when a certain amount of the condensed water is collected.
Composite heat dissipation structure.
A pole formed vertically from the ground and formed so that various electronic devices can be mounted;
An enclosure formed on the pole and configured to accommodate and protect any one of a lighting device, a CCTV, a display, and a control device;
A housing formed inside the enclosure and configured to accommodate a circuit portion of an electronic device;
A constant temperature unit formed inside the housing and configured to constantly control a temperature inside the housing;
A humidity control unit formed inside the housing and configured to constantly control the humidity remaining inside the housing;
A drain unit formed inside the housing and collecting condensed water generated by a temperature difference and discharging it to the outside;
Includes; an environmental sensor formed on the outer surface of the pole and collecting external environmental information to determine the operation of the constant temperature unit and the humidity unit,
The constant temperature unit is
A thermoelectric element formed inside the housing and configured to radiate heat on one side and absorb heat on the other side when power is supplied;
A heat sink formed on one surface and the other surface of the thermoelectric element to increase an area through which heat is diffused and formed of an aluminum material;
Consists of; a heat pipe buried in the heat sink formed on one surface of the thermoelectric element and disposed in a zigzag shape and formed of a copper material to radiate or absorb heat to the heat sink,
Since the heat sink and the heat pipe are formed of different materials, the heat pipe is confined to the inside of the heat sink to limit expansion, thereby preventing damage or cracking due to contraction and expansion due to heat transfer,
The humidity control unit removes moisture remaining in the air inside the housing and operates in reverse through a reverse voltage to supply moisture inside the housing,
The drain unit is characterized in that the drain unit has an N-shaped discharge path formed under the housing, so that the discharged condensate is formed so that external air does not flow in.
Smart structure with complex heat dissipation structure.

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