KR20130100643A - Multi chamber system for life growing experiment - Google Patents

Abstract

PURPOSE: A multi-chamber system is provided to easily vary the growing environment, and to easily measure the growth change of a creature. CONSTITUTION: An inner chamber (200) includes a growing space for growing a creature. An outer chamber (100) isolates the growing space from the external environment, and is installed outside of the inner chamber. An environmental control unit (300) controls the growing environment of the growing space. A first sensor unit (410) controls at least one environment parameter of the outer chamber among the temperature, the humidity, the illumination, the carbon dioxide amount, and the oxygen amount. A second sensor unit controls at least one environment parameter of the inner chamber among the temperature, the humidity, the illumination, the carbon dioxide amount, and the oxygen amount. A growth measurement device (500) measures the growth of a creature by comparing the environment parameters of the first and second sensor units. [Reference numerals] (100) Outer chamber; (200) Inner chamber; (300) Environmental control unit; (410) First sensor unit; (420) Second sensor unit; (500) Growth measurement device

Description

MULTI CHAMBER SYSTEM FOR LIFE GROWING EXPERIMENT}

The present invention relates to a multi-chamber system for a biogrowth experiment, and more particularly, to a multi-chamber system that can easily vary the growth environment by using the multi-chamber, and can easily measure the growth change of the organism.

In the real environment, since the biological growth environment cannot be changed in various ways, the conventional laboratory uses a chamber that can be isolated from the external environment.

However, since the conventional chamber is composed of one single structure, only the environment in the chamber can be adjusted to have a predetermined growth environment, and it is not easy to detect the environmental change caused by the growth process of the organisms in the chamber.

In this regard, there is a need for a chamber that can detect environmental changes caused by the growth process of living organisms while providing a predetermined growth environment, and can provide more diverse environmental conditions.

Accordingly, an object of the present invention relates to a multi-chamber system that can easily vary the growth environment using multiple chambers, and can easily measure the growth change of the organism.

Multi-chamber system of the present invention for achieving the above object, the inner chamber having a growth space for growing the organism, the outer chamber isolating the growth space from the external environment, and disposed outside the inner chamber, and It includes an environmental control device for adjusting the growth environment of the growth space.

In this case, the inner chamber may have a transparent material and include a second fan for selectively introducing air in the outer chamber.

On the other hand, the outer chamber may be provided with a first fan for selectively introducing air from the outside into the inner chamber and the air vent to balance the pressure in the outer chamber with the atmosphere outside.

In this case, the outer chamber may further include a filter unit for removing foreign substances of air introduced through the first fan.

On the other hand, the multi-chamber system, the first sensor unit for detecting at least one environmental factor of the temperature, humidity, illuminance, carbon dioxide amount, oxygen amount in the outer chamber, and the temperature, humidity, illuminance, carbon dioxide in the inner chamber It may further include a second sensor unit for detecting at least one environmental factor of the amount and oxygen amount.

In this case, the environmental control device, it is preferable to adjust the growth environment of the growth space based on the environmental factors measured by the first sensor unit.

On the other hand, the chamber system may further include a growth measuring device for measuring the growth of the organism by comparing the environmental factors measured by the first sensor unit and the environmental factors measured by the second sensor unit.

On the other hand, the environmental control device, lighting unit for providing light in the growth environment, carbon dioxide control unit for adjusting the carbon dioxide in the outer chamber, oxygen control unit for adjusting the oxygen in the outer chamber, adjusting the humidity in the outer chamber Humidity control unit, and may include a temperature control unit for controlling the temperature in the outer chamber.

In this case, it is preferable that the said illumination part provides light in the said growth environment using an LED light source.

In this case, the LED light source is composed of a red LED, a green LED, and a blue LED, and the environmental control device preferably controls the brightness of each of the red LED, the green LED, and the blue LED individually.

On the other hand, the lighting unit is disposed above the inner chamber in the outer chamber, it is preferable that the distance to the inner chamber is adjustable.

On the other hand, the organism is a plant, the environmental control device may further include a nutrient solution providing unit for providing the nutrient solution required for the plant growth.

As described above, the multi-chamber system according to the present embodiment can vary and easily change the growth environment by using the multi-chamber, and can easily measure the growth change of living organisms.

1 is a block diagram showing a configuration of a multi-chamber system according to an embodiment of the present invention;
2 and 3 are views showing the shape of a multi-chamber according to the present embodiment, and
4 is a view showing a specific configuration of the environmental control device of FIG.

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

1 is a block diagram showing the configuration of a multi-chamber system according to an embodiment of the present invention.

Referring to FIG. 1, the multi-chamber system 1000 according to the present embodiment includes an external chamber 100, an internal chamber 200, an environmental control device 300, a plurality of sensor units 400, and a growth measuring device 500. It is composed of

The outer chamber 100 isolates the growth space from the external environment and is disposed outside the inner chamber 200. Specifically, the outer chamber 100 has a sealed structure through the appearance of an opaque material, the first fan, the air introduced through the first fan to selectively introduce air from the outside into the interior of the outer chamber 100 It may be provided with an air vent to balance the pressure in the filter unit and the outer chamber 100 to remove foreign matters of the outside atmosphere. A detailed shape of the outer chamber 100 will be described later with reference to FIGS. 2 and 3.

The inner chamber 200 has a growth space for growing a living organism, and is disposed inside the outer chamber 100. Specifically, the inner chamber 200 may have a sealed exterior structure made of a transparent material, and may include a second fan that selectively introduces air in the outer chamber 100 into the inner chamber 200. A detailed shape of the inner chamber 200 will be described later with reference to FIGS. 2 and 3.

Environmental control device 300 adjusts the growth environment of the growth space. Specifically, the environmental control device 300 may adjust the environmental factors (eg, temperature, humidity, illuminance, carbon dioxide amount, oxygen amount, etc.) in the outer chamber 100 to adjust the growth environment according to the experimental conditions. In the present embodiment, only the adjustment of the environmental factors in the outer chamber 100 has been described. However, as the inner chamber 200 is located in the outer chamber 100, the environmental change in the outer chamber 100 is changed in the inner chamber 200. Will affect.

In addition, the environmental control apparatus 300 may adjust the environment in the inner chamber 200 and the environment in the outer chamber 100 to be different. In addition, in implementation, only certain environmental factors may be adjusted to differ between the inner chamber 200 and the outer chamber 100. For example, in order to observe the change in the amount of carbon dioxide and oxygen of the inner chamber according to the biological growth, the environmental control device 300 adjusts the temperature and humidity so that the inner chamber 200 and the outer chamber 100 are the same. The second fan may be controlled so that air in the outer chamber 100 does not flow into the inner chamber 200 to measure a change in the amount of carbon dioxide and oxygen in the inner chamber 200. Environmental factors controlled in the experimental environment may vary depending on the subject and the experimental conditions.

And the environmental control device 300 may adjust the growth environment therein based on the environmental factors measured by the sensor unit 400 to be described later. Specifically, when the environment control device 300 detects a change in temperature, humidity, illuminance, carbon dioxide amount, and oxygen amount in the internal chamber 200, the environmental control device 300 may adjust the environmental factor so that the changed environmental factor has a predetermined environmental factor value. have. For example, when the temperature in the outer chamber 100 is lower than a predetermined value, the temperature in the outer chamber 100 may be adjusted to have a predetermined value by using the temperature controller 355 to be described later.

In the present embodiment, only an example of adjusting the internal growth environment based on the environmental factors detected in the inner chamber 200 has been described. However, in the implementation, the internal growth based on the environmental factors sensed in the outer chamber 100 is implemented. It can also be implemented in the form of adjusting the environment. In addition, the implementation may also be implemented in the form of using the measured value of a different position for each environmental factor. For example, the temperature factor may be implemented using a value measured in the outer chamber 100, and the illuminance may be implemented using a value measured in the inner chamber 200.

The sensor unit 400 detects environmental factors in the outer chamber 100 and the inner chamber 200. In detail, the sensor unit 400 may include a first sensor unit 410 for detecting environmental factors in the outer chamber 100 and a second sensor unit 420 for detecting environmental factors in the inner chamber 200. have.

The first sensor unit 410 may be a variety of sensors (eg, temperature sensor, humidity sensor) for measuring various environmental factors (eg, temperature, humidity, illuminance, carbon dioxide amount, oxygen amount, etc.) in the outer chamber 100. , A variety of environmental factors in the outer chamber 100 using an illumination sensor, a carbon dioxide sensor, an oxygen sensor, and the like, and transmit the detected values to the environmental controller 300 and the growth measuring apparatus 500. have.

The second sensor unit 420 may include various sensors (eg, temperature sensor, humidity sensor) for measuring various environmental factors (eg, temperature, humidity, illuminance, carbon dioxide amount, oxygen amount, etc.) in the internal chamber 200. , A variety of environmental factors in the inner chamber 200 using an illumination sensor, a carbon dioxide sensor, an oxygen sensor, and the like, and transmit the detected values to the environmental controller 300 and the growth measuring apparatus 500. have.

In the above description, only the temperature, humidity, illuminance, carbon dioxide amount, and oxygen amount have been described as examples of environmental factors. However, other environmental factors may be used in the implementation, and may be implemented in a form using only some of the environmental factors. In addition, although the first sensor unit 410 and the second sensor unit 420 have been described as measuring the same environmental factor, in the implementation, the first sensor unit 410 and the second sensor unit 420 have different environments. Factors may be measured, and some environmental factors may be measured in common, and some environmental factors may be implemented in a form of measuring only one sensor unit. For example, the amount of carbon dioxide and the amount of oxygen are measured in common in the first sensor unit 410 and the second sensor unit 420, and the temperature, humidity, and illuminance are also implemented in the form of measuring only in the second sensor unit 420. Can be.

The growth measuring apparatus 500 compares the environmental factors measured by the first sensor unit 410 and the environmental factors measured by the second sensor unit 420 to measure the growth of living organisms. For example, in a state in which the second fan of the inner chamber 200 is not operated (ie, after the inner chamber 200 is isolated from the outer chamber 100), the amount of carbon dioxide in the inner chamber 200 and the outer chamber The growth of living organisms may be indirectly measured using the difference in the amount of carbon dioxide in the 100 and the difference in the amount of oxygen in the inner chamber 200 and the amount of oxygen in the outer chamber 100.

Although the growth measurement apparatus 500 and the environmental control apparatus 300 are illustrated and described as having separate configurations, the function of the growth measurement apparatus 500 and the function of the environmental control apparatus 300 may be implemented in one configuration. It may be.

As described above, in the multi-chamber system 1000 according to the present exemplary embodiment, the multi-chamber system provides a growth environment for living organisms, and thus, more various growth environments can be adjusted and the growth change of living organisms can be easily measured. do.

2 and 3 are views illustrating the shape of multiple chambers according to the present embodiment. Specifically, FIG. 2 is a front perspective view of the multiple chamber, and FIG. 3 is a rear perspective view of the multiple chamber.

2 and 3, the multiple chamber is composed of an outer chamber 100 and an inner chamber 200.

The outer chamber 100 has a closed structure in the form of a hexahedron. The outer chamber 100 includes a first fan 110 and an air vent 120. At this time, the exterior of the outer chamber 100 preferably has an opaque material so that the external stimulus does not affect the growth environment.

The first fan 110 is located in the upper region of the side of the outer chamber 100 and selectively introduces outside air into the outer chamber 100 under the control of the environmental control device 300. And although not shown, the incoming outside air may be filtered through the filter unit for removing the foreign matter.

The air vent 120 balances the pressure in the outer chamber 100 with the atmosphere.

The inner chamber 200 has a closed structure in the form of a hexahedron. The inner chamber 200 includes a second fan 210. At this time, the appearance of the inner chamber 200 preferably has a transparent material so that the light of the lighting unit 370 provided in the outer chamber 100 is reflected in the growth space.

The second fan 210 is located in an upper region of the side of the inner chamber 200 and selectively introduces air from the outer chamber 100 into the inner chamber 200 under the control of the environmental control device 300.

In addition, the lighting unit 370 of the environmental control device 300 is disposed above the inner chamber upper part 200 in the outer chamber 100. The lighting unit 370 has a structure in which a distance from the inner chamber 200 is adjustable. On the other hand, Figures 2 and 3, but only the configuration of the lighting unit of the environmental control device 300, in the outer chamber 100, various control units to be described later with respect to Figure 4 for controlling the environment in the outer chamber 100 is arranged Can be.

Meanwhile, in the illustrated example, each of the outer chamber 100 and the inner chamber 200 is illustrated as having a hexahedron shape, but may be implemented in various forms other than the hexahedron. In addition, although the door is not illustrated in the illustrated example, the door may be provided at each side of the outer chamber 100 and the inner chamber 200.

Although not shown in FIGS. 2 and 3, the first sensor unit 410 may be disposed at a predetermined position inside the outer chamber 100. In addition, the second sensor unit 420 may be disposed at a predetermined position inside the inner chamber 200.

In FIG. 2 and FIG. 3, the multi-chamber according to the present embodiment is illustrated and described as being composed of two chambers. However, the three chambers may be implemented as three or more chambers. For example, the outer chamber may be configured as one, and may be implemented in a form of two or more inner chambers inside the outer chamber, or may be implemented in a form in which an additional second outer chamber is provided outside the outer chamber. .

4 is a view showing a specific configuration of the environmental control device of FIG.

Referring to FIG. 4, the environmental control device 300 includes a communication interface 310, a user interface 320, a storage 330, a carbon dioxide amount adjusting unit 340, an oxygen amount adjusting unit 345, and humidity control. The unit 350, the temperature controller 355, the nutrient solution providing unit 360, the lighting unit 370, and the controller 380 may be configured.

The communication interface 310 is formed to connect the environmental control device 300 with the sensor unit 400 or the growth measuring apparatus 500, and is wireless or wired through a local area network (LAN) and an internet network. In addition to being connected in a manner, it is also possible to be connected through a USB port or a Bluetooth module.

The communication interface 310 receives the environmental factors sensed by the first sensor unit 410 and the second sensor unit 420. In addition, the communication interface 310 may transmit the environmental factors sensed by the first sensor unit 410 and the second sensor unit 420 to the growth measuring apparatus 500. That is, in FIG. 1, only the form in which the environmental factors detected from the first sensor unit 410 and the second sensor unit 420 are provided to each of the environmental control apparatus 300 and the growth measuring apparatus 500 is illustrated. The environmental factors sensed by the first sensor unit 410 and the second sensor unit 420 may also be implemented in the form provided to the growth measuring apparatus 500 via the environmental control device (300).

The user interface 320 may include a plurality of function keys for user setting or selecting various functions supported by the environmental control device 300, and may display various information provided by the environmental control device 300. The user interface 320 may be implemented as a device in which input and output are simultaneously implemented, such as a touch pad, and may be implemented by combining an input configuration such as a plurality of buttons or a keyboard and a display configuration such as an LCD and an OLED.

The user interface 320 receives a setting value of an environmental factor of a growing environment. In addition, the user interface 320 may display the currently set environmental factors and values of the environmental factors sensed by the sensor 400.

The storage unit 330 may store a setting value for each environmental factor received from the user. The storage unit 330 may store information on environmental factors measured by the sensor unit 400.

The carbon dioxide amount adjusting unit 340 adjusts the carbon dioxide in the outer chamber 100. Adjusting the amount of carbon dioxide in the chamber is a general technique, description thereof will be omitted.

The oxygen amount adjusting unit 345 adjusts the amount of oxygen in the outer chamber 100. Adjusting the amount of oxygen in the chamber is a general technique, description thereof will be omitted.

The humidity controller 350 adjusts the humidity in the outer chamber 100. Specifically, the humidity in the outer chamber 100 may be controlled by using a dehumidifier or a humidifier.

The temperature controller 355 adjusts the temperature in the outer chamber 100. Specifically, the temperature in the outer chamber 100 may be adjusted using a heating device (for example, a heater, etc.) and / or a cooling device (for example, an air conditioner, etc.).

The nutrient solution providing unit 360 provides a nutrient solution for plant growth when the organism for growth in the inner chamber 200 is a plant. Specifically, the nutrient solution providing unit 260 may be composed of a pipe connected to the seedlings on which the plant is cultivated and a pump for providing the nutrient solution to the pipe, and the pump so that the nutrient solution is provided to the seedlings under the control of the controller 380. Can be controlled.

The lighting unit 370 provides light in the growing environment. In detail, the lighting unit 370 may provide light in a growing environment using an LED light source. At this time, the LED light source is composed of a red LED, a green LED and a blue LED, the lighting unit 370 may individually control the brightness of each of the red LED, green LED and blue LED under the control of the controller 390. In this case, the controller 390 may provide the lighting unit 370 with a plurality of pulse width modulation (PWM) for individually controlling the brightness of each of the red LED, the green LED, and the blue LED.

The controller 380 may control each component in the environmental control device 300. In detail, the carbon dioxide amount adjusting unit 340, the oxygen amount adjusting unit 345, the humidity adjusting unit 350, and the temperature adjusting unit may have a growth environment corresponding to an environmental factor value stored and received in the storage unit 130. 355, the nutrient solution providing unit 360, and the lighting unit 370 may be controlled.

Although the above has been illustrated and described with respect to preferred embodiments of the present invention, the present invention is not limited to the above-described specific embodiments, and the present invention belongs to the present invention without departing from the gist of the present invention as claimed in the claims. Anyone of ordinary skill in the art can make various modifications, and such changes are within the scope of the claims.

1000: multi-chamber system 100: outer chamber
200: internal chamber 300: environmental control device
400: growth measuring device

Claims (12)

In the multi-chamber system for biological growth experiment,
An inner chamber having a growth space for growing a living organism;
An outer chamber that separates the growth space from an external environment and is disposed outside the inner chamber; And
Multi-chamber system comprising an environmental control device for adjusting the growth environment of the growth space. The method of claim 1,
Wherein the inner chamber comprises:
And a second fan having a transparent material and selectively introducing air in the outer chamber. The method of claim 1,
The outer chamber,
And a first fan for selectively introducing air from the outside into the outer chamber and an air vent to balance the pressure in the outer chamber with the outside atmosphere. The method of claim 3,
The outer chamber,
The multi-chamber system, characterized in that it further comprises a filter unit for removing the foreign matter of the air introduced through the first fan. The method of claim 1,
A first sensor unit sensing at least one environmental factor among temperature, humidity, illuminance, carbon dioxide amount and oxygen amount in the outer chamber; And
And a second sensor unit configured to sense at least one environmental factor among temperature, humidity, illuminance, carbon dioxide amount and oxygen amount in the inner chamber. The method of claim 5,
The environmental control device,
And a growth environment of the growth space is adjusted based on the environmental factors measured by the first sensor unit. The method of claim 5,
And a growth measuring device comparing the environmental factors measured by the first sensor unit and the environmental factors measured by the second sensor unit to measure the growth of the living organism. The method of claim 1,
The environmental control device,
An illumination unit for providing light in the growth environment;
A carbon dioxide control unit for controlling carbon dioxide in the outer chamber;
An oxygen controller for adjusting oxygen in the outer chamber;
Humidity control unit for controlling the humidity in the outer chamber; And
And a temperature controller for controlling a temperature in the outer chamber. 9. The method of claim 8,
The illumination unit includes:
And a light source in said growing environment using an LED light source. 10. The method of claim 9,
The LED light source is composed of a red LED, a green LED and a blue LED,
The environmental control device,
Chamber system, characterized in that for controlling the brightness of each of the red LED, green LED and blue LED individually. 9. The method of claim 8,
The illumination unit includes:
A chamber system disposed above the inner chamber in the outer chamber, the distance from the inner chamber being adjustable; 9. The method of claim 8,
The organism is a plant,
The environmental control device,
The nutrient solution providing unit for providing the nutrient solution required for the plant growth to the plant; Chamber system further comprising.

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