KR102501871B1 - Air quality sensing system including mobile terminal device - Google Patents

Abstract

The present invention relates to an air quality measurement system including a mobile terminal device. The air quality measurement system, according to the present invention, comprises: an air quality measurement device; a system management server unit; a user terminal device unit; and a manager terminal device unit. According to the present invention, air quality can be easily checked through a mobile communication device.

Description

Air quality measurement system including mobile terminal device {AIR QUALITY SENSING SYSTEM INCLUDING MOBILE TERMINAL DEVICE}

The present invention relates to an air quality measurement system, and more particularly, to an air quality measurement system including a mobile terminal device for measuring and confirming concentrations of fine dust and carbon dioxide in the air.

Fine dust, which has recently become a problem, is a substance with a particle size of 50 μm or less, and causes various diseases when introduced into the human body through breathing.

The fine dust is generated when fossil fuels such as coal and oil are burned, and is mainly generated in factories and automobiles.

On the other hand, volatile organic compounds (VOCs) refer to substances that cause photochemical smog by generating ozone or photochemical oxidizing substances by causing a photochemical reaction by the action of nitrogen oxides and sunlight in the air.

Volatile organic compounds as described above may also be generated in indoor furniture and building materials, and fine dust is a problem because it is introduced into the room from the outside and deteriorates the environment.

In this situation, air quality measuring devices including fine dust, volatile organic compounds, and carbon dioxide concentrations have recently been developed and disseminated.

On January 6, 2019, the applicant of the present invention has filed an application for the title of "air quality measuring device including an air flow path structure" (application number: 10-2019-0005573) and has been registered.

In the air quality measuring device, external air is introduced into an air inlet formed at an upper end of the device and flows to the rear surface of the printed circuit board through a flow passage formed between the outer housing of the device and the printed circuit board.

As described above, the air flowing to the rear surface of the printed circuit board is configured to flow into a housing containing the fine dust sensor and then flow out through an outlet by a blowing fan.

However, in the device, since the air introduced from the outside into the air inlet flows along the surface of the printed circuit board to the lower end of the device and then flows to the rear surface of the printed circuit board, heat generated from the printed circuit board in this process. will be delivered.

After all, these points can be factors that affect measured values such as air temperature, humidity, and fine dust concentration.

In addition, moisture may enter the device through the air inlet formed on the upper surface of the device, which reduces the lifespan of the device and greatly affects the measured air temperature and humidity.

In addition, in the device, the organic compound sensor, the carbon dioxide sensor, and the temperature and humidity sensor are disposed on the front side of the printed circuit board, and the fine dust sensor is disposed on the rear side of the printed circuit board, which is a factor in increasing the thickness of the entire device.

In addition, since the air quality measuring device does not interwork with a mobile terminal device such as a smart phone, there is a limitation in that the air quality detected by the air quality measuring device cannot be remotely checked.

The present invention has been made to solve the above problems, and an object of the present invention is configured to interlock an air quality measuring device and a mobile mobile communication device so that air quality can be easily checked through the mobile communication device It is to provide an air quality measurement system including a mobile terminal device.

Another object of the present invention is an air quality measuring system including a mobile terminal device configured to give a warning through the mobile communication device when data related to air quality received from an external institution or air quality measuring device exceeds a reference value. is to provide

Another object of the present invention is to provide an air quality measurement system including a mobile terminal device in which an air flow path flowing in from the outside is configured very simply to measure air quality through an air quality measurement device.

Another object of the present invention is that the air flow space in the air quality measuring device is configured to be distinguished from other spaces in the device, so that other components of the air quality measuring device do not affect the air flowing in from the outside. It is to provide an air quality measuring system comprising a device.

Another object of the present invention is to provide an air quality measurement system including a slim and compact mobile terminal device by reducing the thickness of the air quality measurement device.

Another object of the present invention is to provide an air quality measuring system including a mobile terminal configured to efficiently dissipate heat generated from the air quality measuring device while preventing moisture penetration into the air quality measuring device.

An air quality measuring system including a mobile terminal device according to the present invention for achieving the above object includes an air quality measuring device for measuring air quality at an installation site, a system management server configured to communicate with the air quality measuring device through an Internet network, and It includes a user terminal device configured to communicate with the air quality measurement device over an Internet network, and a manager terminal device configured to communicate with the air quality measurement device over an Internet network, wherein a plurality of air quality measurement devices are installed, and the user terminal device unit A plurality of items are included, and among the items displayed on the display unit of the air quality measuring device, a predetermined item is configured to be identically displayed on the display unit of the user terminal device.

Preferably, an external meteorological environment data server unit is connected to the system management server unit to receive data related to air quality from the meteorological environment data server unit.

Here, when a pre-designated item in the data related to air quality exceeds a reference value, the user terminal device unit may be notified.

In addition, when a predetermined item in air quality sensed by the air quality measurement device exceeds a reference value, the user terminal device may be notified.

On the other hand, the air quality measuring device includes a front housing forming a front appearance, a display panel disposed on the front housing, a rear housing forming a rear surface of the air quality measuring device, and a middle disposed between the front housing and the rear housing. It includes a housing, the front housing and the middle housing are fitted together, the middle housing and the rear housing are fitted together, a printed circuit board is disposed inside the air quality measuring device, and the air quality measuring device is disposed on the front side of the printed circuit board. Circuit components for driving the measuring device are disposed, a sensor member for measuring air quality is disposed on the rear surface of the printed circuit board, and an air inlet for air inflow and an air outflow are disposed on the side of the intermediate housing. An air outlet for air is formed, the sensor member includes a sensor member housing, the sensor member housing has a sensor member housing inlet for air inflow and a sensor member housing outlet for air out, and the sensor member housing has an air outlet for air flow. A housing fan for flowing air is installed in the housing, and is configured to introduce air through the sensor member housing inlet and discharge air through the sensor member housing outlet. An inlet partition and an outlet partition are formed inside the air outlet, so that the air introduced into the air inlet is introduced into the sensor member housing inlet through the inlet partition, and the air discharged through the sensor member housing outlet is The air is discharged to the outlet through the outlet partition, and an air flow blocking partition is formed across the inlet partition and the outlet partition, so that the edge portion of the printed circuit board is placed in contact with the air flow blocking partition. to be characterized

Preferably, an edge portion of the printed circuit board is disposed in contact with the air flow blocking partition wall, so that a space inside the inlet partition wall and the outlet partition wall and a front space of the printed circuit board are divided and divided.

Here, the sensor member housing may be formed in a flat hexahedral shape, so that portions other than the sensor member housing inlet and sensor member housing outlet are sealed.

In the sensor member housing, air flow blocking protrusions may be formed at sides of the inlet partition wall and the outlet partition wall to face the air flow blocking partition wall.

In addition, a sensor member accommodating concave portion for accommodating the sensor member may be formed in a portion of the rear housing where the sensor member is disposed.

In addition, rear housing ventilation openings may be formed on the opposite side of a portion of the rear housing where the sensor member is disposed.

Preferably, support partition walls and substrate support partition walls are formed across the support partition walls in the intermediate housing.

Meanwhile, a front panel coupling opening for coupling the front panel may be formed at an edge portion of the front housing.

In addition, a front housing coupling protrusion protrudes from the rear surface of the front panel coupling opening, and an intermediate housing coupling protrusion is formed at a position corresponding to the intermediate housing, so that the intermediate housing coupling projection is formed on the front housing coupling projection. It can be inserted into the projection opening and coupled.

Preferably, a heat dissipation member is disposed between the front housing and the display panel.

Here, the heat dissipation member is formed of a metal plate material, and a rim edge portion of the heat dissipation member may be bent and fitted into the front housing.

In addition, a front housing ventilation opening may be formed at one side of the front housing, and a side portion of the heat dissipation member may be exposed toward the printed circuit board through the front housing ventilation opening.

Preferably, a heat dissipation opening is formed at an edge portion of the heat dissipation member.

In addition, an edge concave portion may be formed at an edge portion of the heat dissipation member.

In addition, front housing heat dissipation concave portions may be formed on a surface of the front housing facing the heat dissipation member.

In addition, grid-shaped concave portions may be formed on the surface of the heat dissipation member.

According to the present invention, the air quality measuring device and the mobile communication device are configured to interlock, so that air quality can be easily checked through the mobile communication device.

In addition, when data related to air quality received from an external institution or an air quality measuring device exceeds a reference value, a warning can be issued through the mobile communication device, so that air quality can be prepared in advance.

In addition, since the air flow path flowing in from the outside of the air quality measurement device is configured very simply, the accuracy of air quality measurement can be increased.

In addition, the air flow path is clearly separated from other spaces inside the air quality measuring device, so that the air introduced from the outside and the components of the device do not affect each other.

In addition, by efficiently dissipating heat generated from the device while preventing moisture penetration into the air quality measuring device, the useful life of the device can be increased.

In addition, by reducing the thickness of the air quality measuring device, it can be configured to be more slim and compact.

The accompanying drawings are for understanding the technical spirit of the present invention together with the detailed description of the invention, and the present invention should not be construed as being limited to the matters shown in the drawings.
1 is a block diagram of an air quality measuring system including a mobile terminal device according to the present invention;
2 is a front view of a user terminal device and an air quality measurement device included in the system;
3 is a block diagram of the air quality measurement device,
4 is a front perspective view of an air quality measuring device included in the system;
5 is an exploded perspective view of the measuring device;
6 is a perspective view of a state in which the front housing is removed from the measuring device;
7 is a rear perspective view of the measuring device in a state in which the rear housing is removed;
8 is a rear perspective view of the measuring device according to another embodiment of the present invention;
9 is a perspective view of a state in which an intermediate housing included in the measuring device is viewed from below,
10 is a perspective view of the intermediate housing viewed from above,
11 is a perspective view of a rear housing included in the measuring device;
12 is a perspective view of a front housing included in the measuring device viewed from the front;
13 is a perspective view of a state in which the front housing is coupled to the intermediate housing as seen from the front;
14 is an exploded perspective view of a front housing, a display panel, and a front panel included in the measuring device;
15 is an exploded perspective view of a front housing, a heat dissipation member, and a display panel included in the measuring device;
16 is a perspective view of a state in which a heat dissipation member is coupled to the front housing;
17 is a perspective view of a front housing according to another embodiment of the present invention;
18 is a perspective view of a heat dissipation member according to another embodiment of the present invention.

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

Prior to this, the terms used in this specification and claims should not be construed as limited in a dictionary sense, and based on the principle that the inventor can appropriately define the concept of terms in order to best explain his/her invention. , It should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, so various equivalents that can replace them at the time of this application It should be understood that water and variations may exist.

1 is a configuration diagram of an air quality measuring system including a mobile terminal device according to the present invention, FIG. 2 is a front view of a user terminal device included in the system and an air quality measuring device, and FIG. 3 is a configuration of the air quality measuring device 4 is a front perspective view of the air quality measuring device included in the system, FIG. 5 is an exploded perspective view of the measuring device, and FIG. 6 is a perspective view of the measuring device with the front housing removed. 7 is a rear perspective view of the measuring device in a state in which the rear housing is removed, FIG. 8 is a rear perspective view of the measuring device according to another embodiment of the present invention, and FIG. 9 is a bottom view of the intermediate housing included in the measuring device. Fig. 10 is a perspective view of the intermediate housing viewed from above, Fig. 11 is a perspective view of the rear housing included in the measuring device, and Fig. 12 is a perspective view of the front housing included in the measuring device. Fig. 13 is a perspective view of a state in which the front housing is coupled to the intermediate housing as viewed from the front, and Fig. 14 is an exploded perspective view of the front housing, display panel, and front panel included in the measuring device. 15 is an exploded perspective view of a front housing, a heat dissipation member, and a display panel included in the measuring device, FIG. 16 is a perspective view of a state in which a heat dissipation member is coupled to the front housing, and FIG. 17 is another embodiment of the present invention. 18 is a perspective view of a heat dissipation member according to another embodiment of the present invention.

1 and 2, an air quality measurement system including a mobile terminal device according to the present invention is configured to communicate with an air quality measurement device 10 for measuring air quality at an installation site and an internet network communication with the air quality measurement device 10 A system management server unit 8 configured, a user terminal device unit 3 configured to communicate with the air quality measuring device 10 through an Internet network, and a manager terminal configured to communicate with the air quality measuring device 10 through an Internet network It includes a device part (2).

In the air quality measuring system according to the present invention, a plurality of air quality measuring devices 10 are installed in a plurality of locations.

The air quality measuring device 10 is a device for measuring the concentration of fine dust, the concentration of carbon dioxide, temperature, humidity, etc. in the air through a sensing unit for detecting the air quality by flowing air into the device.

The air quality measuring device 10 may be installed in a plurality of locations, such as a school, for example.

Alternatively, the air quality measuring device 10 may be installed in a plurality of schools and configured to detect air quality.

And, the air quality sensed as described above is configured to be displayed through the display unit of the air quality measuring device 10 .

Thus, the air quality can be checked through the display unit at the place where the air quality measuring device 10 is installed.

The system management server unit 8 refers to a server used by an air quality measuring system manager according to the present invention.

A terminal device (not shown) used by the system manager is connected to the system management server unit 8 to input/output various data.

The air quality measurement device 10 may be configured to communicate with the system management server unit 8 through an internet network through a communication unit.

Thus, a driving program stored in the memory unit of the air quality measuring device 10 may be upgraded through the system management server unit 8 or an operation status of the air quality measuring device 10 may be grasped.

As a method for mutual network communication between the system management server unit 8 and the air quality measurement device 10, a wireless Internet communication method using the Internet of Things method or a wired Internet communication method through an Internet communication line connection may be used.

In addition, the user terminal device unit 3 may be typically composed of a smart phone, and the user terminal device unit 3 is also included in plurality.

For example, the user terminal device unit 3 may be a smart phone used by teachers working in schools.

Alternatively, the user terminal device units 3 may be configured as smart phones possessed by teachers working in a plurality of different schools.

The user terminal device unit 3 is configured to communicate with the air quality measuring device 10 through an Internet network.

Meanwhile, as the manager terminal device unit 2, a desktop computer and a monitor may be mainly used, but a smart phone may also be used.

The manager terminal device unit 2 is configured to communicate with the air quality measurement device 3 and the user terminal device unit 3 through an Internet network.

As described above, the air quality detected by the sensing unit of the air quality measuring device 10 is displayed on the display unit as a number.

Thus, it is possible to check air quality measurement values through the display unit of the air quality measuring device 10 .

The measured value may be, for example, the concentration of fine dust including the temperature and humidity of the air, the concentration of carbon dioxide, the concentration of ozone, the concentration of carbon monoxide, and the like.

In the system according to the present invention, among the items displayed on the display unit of the air quality measuring device 10, the predetermined items are configured to be identically displayed on the display unit of the user terminal device unit 3.

Examples of the predetermined items may include temperature and humidity, concentration of fine dust, and concentration of carbon dioxide at a place where the air quality measuring device 10 is installed.

Thus, for example, school teachers can check the air quality detected by the air quality measuring device 10 installed outdoors using their smart phone.

In this way, it is possible to warn students who intend to use the playground or the like in advance.

Meanwhile, an external meteorological environment data server unit 7 may be connected to the system management server unit 8 .

The meteorological environment data server unit 7 may be, for example, a data server of the Korea Meteorological Administration.

Also, the system management server unit 8 may be configured to receive data related to air quality from the meteorological environment data server unit 7 .

The data related to the air quality may be, for example, the concentration of fine dust in the air, temperature, or ozone concentration.

And, in the data related to air quality transmitted from the meteorological environment data server unit 7, if a predetermined item such as fine dust concentration or temperature exceeds a reference value, this fact is transmitted to the user terminal device unit 3. Can be configured to notify.

Thus, when the fine dust concentration or temperature is very high, teachers can check this through their own user terminal device unit 3 and warn students who want to use the playground.

In addition, even when the air quality detected by the air quality measuring device 10 exceeds the reference value, the user terminal device unit 3 may be notified.

Meanwhile, as shown in FIGS. 4 and 5, the air quality measuring device 10 includes a front housing 12 forming a front appearance of the air quality measuring device, and a display panel 13 disposed on the front housing 12. and a rear housing 16 forming a rear surface of the air quality measuring device, and an intermediate housing 14 disposed between the front housing 12 and the rear housing 16.

Here, the front housing 12 and the middle housing 14 are fitted, the middle housing 14 and the rear housing 16 are fitted, and the printed circuit board P is inside the air quality measuring device. are placed

In addition, circuit components for driving the air quality measuring device are disposed on the front surface of the printed circuit board (P), and a sensor member 17 for measuring air quality is disposed on the rear surface of the printed circuit board (P).

In addition, an air inlet 142 for inflow of air and an air outlet 144 for outflow of air are formed on the side of the middle housing 14 .

Further, the sensor member 17 includes a sensor member housing 172, and the sensor member housing 172 includes a sensor member housing inlet 174 for air inflow and a sensor member housing outflow for air outflow. Section 176 is formed.

In addition, a housing fan 178 for flowing air is installed in the sensor member housing 172 to introduce air through the sensor member housing inlet 174 and the sensor member housing outlet 176. It is configured to discharge air through.

In addition, inlet partition walls 145 and 146 and outlet partition walls 146 and 147 are formed inside the air inlet 142 and the air outlet 144 at the side of the intermediate housing 14, The air introduced into the air inlet 142 is introduced into the sensor member housing inlet 174 through the inlet partition walls 145 and 146 .

In addition, the air discharged through the sensor member housing outlet 176 is discharged to the air outlet 144 through the outlet partition walls 146 and 147 .

Preferably, an air flow blocking partition wall 148 is formed across the inlet partition walls 145 and 146 and the outlet partition walls 146 and 147, so that the printed circuit board ( The edge portion E of P) is placed in contact.

Looking more specifically, the front housing 12 is a configuration for forming the front appearance of the air quality measuring device according to the present invention.

The front housing 12 is formed of a synthetic resin material and has a substantially rectangular frame shape, and a display panel 13 for displaying temperature, humidity, fine dust concentration, etc. in letters and numbers is disposed inside.

The display panel 13 may be composed of an LCD display panel.

In front of the display panel 13, a front panel 11 made of synthetic resin is disposed.

An intermediate housing 14 is disposed between the front housing 12 and the rear housing 16 .

The intermediate housing 14 is also made of synthetic resin and is formed in a substantially rectangular frame shape, and is coupled to the front housing 12 by a fitting method.

An air inlet 142 for inflow of external air and an air outlet 144 for outflow of air are formed on the side of the middle housing 14 .

The printed circuit board (P) for driving the air quality measurement device is disposed in the middle housing (14).

Various circuit components for driving the air quality measurement device are disposed on the front surface of the printed circuit board (P), and a sensor member 17 for measuring air quality is disposed on the rear surface of the printed circuit board (P).

As shown in FIG. 7, the sensor member 17 includes a sensor member housing 172 formed in a flat hexahedral shape, and various sensors for measuring air quality are disposed inside the sensor member housing 172 .

The various sensors include, for example, a fine dust concentration measurement sensor for measuring the concentration of fine dust in the air, a temperature measurement sensor for measuring temperature, a humidity measurement sensor for measuring humidity, and a carbon dioxide concentration measurement for measuring carbon dioxide concentration. A sensor and a sensor for measuring the concentration of an organic compound may be included.

The sensor member housing 172 is formed with a sensor member housing inlet 174 for air inflow and a sensor member housing outlet 176 for air out.

In addition, a housing fan 178 for flowing air is installed inside the sensor member housing 172.

Thus, by driving the housing fan 178, air is introduced through the sensor member housing inlet 174 and air is discharged through the sensor member housing outlet 176.

And, in the process of air flow through the sensor member housing inlet 174 and the sensor member housing outlet 176, it is configured to pass through various sensors disposed inside the sensor member housing 172.

Preferably, parts of the sensor member housing 172 other than the sensor member housing inlet 174 and the sensor member housing outlet 176 are configured to be sealed.

On the other hand, as shown in Figures 5 to 7, the inside of the air inlet 142 and the air outlet 144 on the side of the intermediate housing 14, the inlet partition wall (145, 146) and the outlet partition wall (146, 147) is formed.

Thus, the air introduced into the air inlet 142 formed on the side of the intermediate housing 14 flows into the sensor member housing inlet 174 through the inlet partition walls 145 and 146 .

Due to the inlet partition walls 145 and 146, the air introduced into the air inlet 142 does not flow from the rear surface of the printed circuit board P to an area other than the sensor member housing 172, but completely. It may be guided and flowed into the sensor member housing inlet 174 .

Then, the air introduced into the sensor member housing inlet 174 as described above flows inside the sensor member housing 172 formed in a sealed state, and is discharged through the sensor member housing outlet 176, The air is completely guided and discharged to the air outlet 144 through the outlet partition walls 146 and 147 .

Thus, the air introduced into the air inlet 142 formed on the side of the intermediate housing 14 does not flow from the rear surface of the printed circuit board P to other areas, and penetrates the inside of the sensor member housing 172. It can be discharged after flowing.

With this configuration, since the outside air flows only into the sensor member housing 172, it is not affected by various circuit components included in the air quality measuring device according to the present invention.

Thus, it is possible to increase the accuracy of air quality measurement including the temperature and humidity of the outside air and the concentration of fine dust.

In addition, in the state in which the inlet partition walls 145 and 146 and the outlet partition walls 146 and 147 are formed as described above, air flows across the inlet partition walls 145 and 146 and the outlet partition walls 146 and 147. A blocking barrier 148 is formed.

Also, the edge portion E of the printed circuit board P is disposed in contact with the air flow blocking barrier 148 .

In the state in which the air flow blocking partition 148 is formed across the inlet partition walls 145 and 146 and the outlet partition walls 146 and 147 as described above, the printed circuit board (P) is attached to the air flow blocking partition wall 148. ) is placed in contact with the edge portion E, so that the printed circuit board P serves as a barrier against air flow.

Thus, the space inside the inlet partition walls 145 and 146 and the outlet partition walls 146 and 147 and the front space of the printed circuit board P may be separated and blocked.

According to the configuration of the present invention, the air inside the inlet partition walls 145 and 146 and the outlet partition walls 146 and 147 can be prevented from flowing toward the front space of the printed circuit board P. .

On the other hand, in order to more thoroughly separate the space partitioned by the inlet partition walls 145 and 146 and the outlet partition walls 146 and 147 from other spaces inside the air quality measuring device according to the present invention, as shown in FIG. As described above, an air flow blocking protrusion 175 may be formed in the sensor member housing 172 .

The air flow blocking protrusion 175 is disposed to face the air flow blocking barrier 148 in a state in which it protrudes toward the inlet partition walls 145 and 146 and the outlet partition walls 146 and 147.

Meanwhile, as shown in FIGS. 9 and 10 , support partition walls 1452 and substrate support partition walls 1454 are formed across the support partition walls 1452 in the intermediate housing 14 .

In addition, the edge portion of the printed circuit board P is disposed in contact with the substrate supporting barrier rib 1454 .

Thus, the printed circuit board (P) can be stably disposed inside the intermediate housing (14).

And, as shown in FIG. 11, the rear housing 16 is also formed of a synthetic resin material and has a rectangular shape as a whole.

On the rear surface of the intermediate housing 14, the rear housing 16 is fitted and coupled, and screws may be additionally coupled to secure coupling strength.

A sensor member accommodating concave portion 162 for accommodating the sensor member may be formed in a portion of the rear housing 16 where the sensor member 17 is disposed.

Since the sensor member 17 formed in the flat hexahedral shape is accommodated in the sensor member accommodating concave portion 162, the thickness of the entire device can be reduced.

In addition, rear housing ventilation openings 164 may be formed on the opposite side of the rear housing 16 where the sensor member 17 is disposed.

Thus, as external air flows to the rear surface of the printed circuit board (P) through the rear housing ventilation opening 164, heat generated from various circuit components disposed on the front surface of the printed circuit board (P) is reduced. can be effectively cooled.

Meanwhile, as shown in FIGS. 12 and 13 , a front panel coupling opening 122 for coupling the front panel 11 may be formed at an edge of the front housing 12 .

The front panel 11 is made of a synthetic resin material, and the portion where the display panel 13 is disposed is formed transparently so that numbers and characters displayed on the display panel 13 can be seen.

Coupling protrusions 112 are formed at the edge of the front panel 11, and the coupling protrusions 112 are fitted into the front panel coupling opening 122, so that the front panel 11 is attached to the front housing ( 12) can be placed on the front side.

In addition, a front housing coupling protrusion 124 is protruded from the rear surface of the front panel coupling opening 122 in the front housing 12 .

In addition, as shown in FIG. 13 , an intermediate housing coupling protrusion 1456 is formed at a position corresponding to the front housing coupling protrusion 124 in the intermediate housing 14 .

Thus, the middle housing coupling protrusion 1456 is inserted into the coupling protrusion opening 125 formed in the front housing coupling protrusion 124, so that the front housing 12 and the middle housing 14 can be coupled.

Meanwhile, as shown in FIG. 15 , a heat dissipation member 15 may be disposed between the front housing 12 and the display panel 13 .

The heat dissipation member 15 is formed of a thin metal plate material such as steel or aluminum alloy, and the edge portion 152 of the heat dissipation member 15 is bent.

As described above, in a state where the edge portion 152 of the heat dissipation member 15 is bent, the heat dissipation member 15 may be fitted into the front portion of the front housing 12 .

As shown in FIGS. 15 and 16 , a front housing ventilation opening 126 is formed on one side of the front housing 12 .

In this state, the side portion S of the heat dissipation member 15 is configured to protrude toward the front housing vent 126 side.

The front housing ventilation opening 126 is formed to face the rear housing ventilation opening 164 formed in the rear housing 16 .

Thus, the side portion S of the heat dissipation member 15 to which the heat generated from the display panel 13 is transferred is efficiently cooled by the air flowing through the rear housing ventilation opening 164.

In addition, heat dissipation openings 153 may be formed in the edge portion 152 of the heat dissipation member 15 .

Preferably, some of the heat dissipation openings 153 are formed at positions corresponding to the front housing coupling protrusions 124 formed on the front housing 12 .

Thus, the air flowing into the front housing coupling protrusion 124 and the coupling protrusion opening 125 formed therein can flow to the heat dissipation opening 153 portion.

Thus, the cooling effect of the heat dissipation member 15 may be increased.

In addition, edge concave portions 155 may be formed at the edge of the heat dissipation member 15 .

The rim portion 152 of the heat dissipating member 15 is easily bent by the rim concave portions 155 so that it can be fitted into the front housing 12 .

In another embodiment of the present invention shown in FIG. 17 , front housing heat dissipation concave portions 128 may be formed on a surface of the front housing 12 facing the heat dissipation member 15 .

Thus, the air flowing through the front housing ventilation opening 126 flows into the front housing heat dissipating concave portion 128, so that the entire heat dissipating member 15 can be cooled more effectively.

And, in another embodiment of the present invention shown in FIG. 18, surface concave portions 156 in a lattice shape may be formed on the surface of the heat dissipating member 15.

The surface concave portion 156 may be formed on a surface of the heat dissipating member 15 in contact with the display panel 13 or on both sides.

The surface area of the heat dissipation member 15 itself is increased by the surface concave portions 156, so that heat transfer efficiency can be increased.

In addition, as air flows through the surface concave portion 156 , the display panel 13 disposed on the front surface of the heat dissipating member 15 can be more effectively cooled.

Above, the terms used in the embodiments of the present invention have the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs.

Although the present invention has been described with limited embodiments and drawings, the above embodiments are not intended to limit the technical idea of the present invention but to explain it, so the technical idea of the present invention is not limited to these, and the present invention belongs Various modifications and variations will be possible by those skilled in the art within the scope of equivalents of the technical spirit of the present invention and the claims to be made below.

Therefore, the protection scope of the present invention should be construed according to the claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

And, if it is within the scope of the object of the present invention, all of the components may be configured by selectively combining one or more.

The term "includes" or "consists of" described above means that the corresponding component may be included, and should be interpreted as being able to additionally include other components.

2: manager terminal device unit
3: user terminal device unit
8: system management server unit
10: air quality measuring device
11: front panel
12: front housing
13: display panel
14: middle housing
15: heat dissipation member
16: rear housing
17: sensor member

Claims (20)

An air quality measuring device for measuring air quality at the installation site;
a system management server configured to communicate with the air quality measuring device through an Internet network;
a user terminal device configured to communicate with the air quality measuring device over an internet network;
And a manager terminal device configured to communicate with the air quality measuring device over an Internet network,
A plurality of air quality measurement devices are installed,
The user terminal device includes a plurality of units,
Among the items displayed on the display unit of the air quality measurement device, a predetermined item is configured to be identically displayed on the display unit of the user terminal device unit,
The system management server unit is connected to an external meteorological environment data server unit,
It is configured to receive data related to air quality from the meteorological environment data server unit,
When a pre-specified item in the data related to air quality exceeds a reference value, it is configured to notify the user terminal device unit,
When a predetermined item in air quality detected by the air quality measuring device exceeds a reference value, configured to notify the user terminal device unit,
The air quality measuring device,
a front housing forming the front exterior of the air quality measuring device;
a display panel disposed on the front housing;
a rear housing forming a rear surface of the air quality measuring device;
Including an intermediate housing disposed between the front housing and the rear housing,
A printed circuit board is disposed in the middle housing portion inside the air quality measuring device,
In the intermediate housing, support partition walls and substrate support partition walls are formed across the support partition walls, and an edge portion of the printed circuit board is disposed in contact with the substrate support partition walls,
Circuit components for driving the air quality measuring device are disposed on the front surface of the printed circuit board,
A sensor member for measuring air quality is disposed on the rear surface of the printed circuit board,
The sensor member includes a fine dust concentration measuring sensor, a temperature measuring sensor, and a humidity measuring sensor,
An air inlet for inflow of air and an air outlet for outflow of air are formed on the side of the middle housing,
The sensor member includes a sensor member housing,
In the sensor member housing, a sensor member housing inlet for air inflow and a sensor member housing outlet for air outflow are formed,
A housing fan for flowing air is installed in the sensor member housing, and configured to introduce air through the sensor member housing inlet and discharge air through the sensor member housing outlet,
An inlet partition wall and an outlet partition wall are formed inside the air inlet and the air outlet on the side of the intermediate housing,
The air introduced into the air inlet is introduced into the sensor member housing inlet through the inlet partition wall,
The air discharged through the sensor member housing outlet is discharged to the air outlet through the outlet partition,
An air flow blocking partition is formed across the inlet partition wall and the outlet partition wall,
An edge portion of the printed circuit board is disposed in contact with the air flow blocking partition,
The mobile terminal device according to claim 1 , wherein an edge portion of the printed circuit board is disposed in contact with the air flow blocking partition wall, so that a space inside the inlet partition wall and the outlet partition wall is separated from a front space of the printed circuit board. Air quality measurement system comprising a. According to claim 1,
The air quality measurement system including a mobile terminal device, characterized in that the sensor member housing is formed in a flat hexahedral shape, so that portions other than the sensor member housing inlet and sensor member housing outlet are sealed. According to claim 2,
The air quality measuring system including a mobile terminal device, characterized in that air flow blocking protrusions are formed at the sides of the inlet partition wall and the outlet partition wall in the sensor member housing to face the air flow blocking partition wall. According to claim 3,
An air quality measurement system including a mobile terminal device, characterized in that a sensor member accommodating concave portion for accommodating the sensor member is formed in a portion of the rear housing where the sensor member is disposed. According to claim 4,
The air quality measuring system including a mobile terminal device, characterized in that the rear housing ventilation openings are formed on the opposite side of the rear housing where the sensor member is disposed. According to claim 1,
An air quality measurement system including a mobile terminal device, characterized in that a front panel coupling opening for coupling the front panel is formed at an edge portion of the front housing. According to claim 6,
A front housing coupling protrusion protrudes from the rear surface of the front panel coupling opening,
An intermediate housing coupling protrusion is also formed at a corresponding position in the intermediate housing,
The air quality measurement system including a mobile terminal device, characterized in that the middle housing coupling protrusion is inserted into and coupled to the coupling protrusion opening formed in the front housing coupling protrusion. According to claim 7,
An air quality measurement system including a mobile terminal device, characterized in that a heat dissipation member is disposed between the front housing and the display panel. According to claim 8,
The air quality measurement system including a mobile terminal device, characterized in that the heat dissipation member is formed of a metal plate material, and a rim edge portion of the heat dissipation member is bent and fitted to the front housing. According to claim 9,
A front housing ventilation opening is formed on one side of the front housing,
The air quality measurement system including a mobile terminal device, characterized in that the side of the heat dissipation member is configured to be exposed toward the printed circuit board through the front housing ventilation opening. According to claim 10,
An air quality measuring system including a mobile terminal device, characterized in that a heat dissipation opening is formed at an edge portion of the heat dissipation member. According to claim 11,
An air quality measurement system including a mobile terminal device, characterized in that an edge concave portion is formed at an edge portion of the heat dissipation member. According to claim 12,
An air quality measurement system including a mobile terminal device, characterized in that front housing heat dissipation concave portions are formed on a surface of the front housing facing the heat dissipation member. According to claim 11,
The air quality measuring system including a mobile terminal device, characterized in that surface concave portions in the form of a lattice are formed on the surface of the heat dissipation member. delete delete delete delete delete delete

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