KR20200100273A - Greenhouse using transparent solar cell - Google Patents

Abstract

A greenhouse using a semi-transparent solar battery is disclosed. Provided is the greenhouse which allows light in a specific wavelength required for plant growth to pass through by using the semi-transparent solar battery, and controls greenhouse environments or generates extra electricity by solar energy generation using light in other wavelengths which has not passed.

Description

Greenhouse using transparent solar cell

The present invention relates to a greenhouse using a translucent solar cell, and more particularly, to a greenhouse capable of solar power generation by configuring the outside of the greenhouse with solar cells.

Existing greenhouses consist of transparent glass or secrets, which only transmit light from the outside, but have no function of generating energy by using the light. In order to provide suitable conditions for plant growth, not only the temperature but also the amount of light must be adjusted, and for this purpose, it is common to control the amount of irradiation to the plant by using a screen or the like. In addition, even in a greenhouse in which solar cells are attached, the solar cells are simply attached to a part of the greenhouse, and the wavelength of sunlight incident into the greenhouse cannot be selected.

Prior art literature

Patent Document (Patent Document 0001) Patent Document 1: Registered Patent Publication No. 10-1094972 (registered on December 9, 2011)

(Patent Document 0002) Patent Document 2: Registered Patent Publication No. 10-1090416 (registered on November 30, 2001)

The technical problem to be achieved by the present invention is to generate electricity by supplying light required for plant growth at an appropriate intensity by using a translucent solar cell capable of selecting a transmitted wavelength and transmittance, and generating electricity by generating solar power with extra light. It is to provide a greenhouse that can be made.

As a means to achieve the above object,

The present invention is installed on the outer wall of a greenhouse, a translucent solar cell that transmits a specific wavelength of light and generates solar power using light of the remaining wavelengths that are not transmitted; A dust measuring means installed at one end of the greenhouse to measure dust and output an alarm signal if it is above a standard; And a odor application device that is electrically connected to the dust measuring means and outputs odor to the outside according to a control signal of the dust measuring means, wherein the translucent solar cell is a dye-sensitized solar cell with light having a wavelength of 400 to 600 nm or It is characterized by using light of 600~800nm wavelength for solar power generation.

In addition, the dust measuring means, a wire mesh (10a) for removing moisture from the dust and guiding only the correct dust to pass, a rotary motor (10b) for accelerating the removal of moisture existing in the air by rotating the wire mesh, and the Electric means for providing heater heat (10c) for supplying heat to the wire mesh to evaporate moisture in contact with the wire mesh at a high speed, and infrared transmission means (A) for emitting infrared rays to detect dust passing through the wire mesh And, an infrared receiving means (B) positioned to face the infrared transmitting means and configured to receive light emitted from the infrared transmitting means to determine the inflow of dust according to the degree of the received amount, and the infrared receiving means (B It is characterized by including a dust measurement control unit (C) for controlling the input voltage of the infrared transmission means (A) to increase when the output voltage of) is less than a set value.

In addition, the odor application device 1100 includes a housing 1110; A battery 1120 installed inside the housing 1110 and receiving power from the outside to charge electricity and then supply electricity to the device; A rotary motor (1130) electrically connected to the battery to receive power from the battery and convert it into a mechanical rotary motion; A motor shaft (1131) installed on the central axis of the rotary motor to rotate in response to the rotation of the rotary motor, but having a bottom surface in a waveform shape and continuously rotating in a curved waveform shape; A vertical drive cylinder (1140) located at the lower end of the rotary motor and flowing while moving up and down by converting the rotation of the rotary motor into a reciprocating vertical motion; It is located above the vertical drive cylinder 1140, but is located on the central axis, and is mechanically contacted while being in contact with the motor shaft 1131 of the rotary motor 1130, and is coupled with the motor shaft 1131 of the rotary motor 1130. And a rotation shaft 1141 for elevating and descending while repeating the separation. Installed on the outer periphery of the vertical driving cylinder 1140, one side is fixed to the locking jaw inside the housing and the other side is fixed to the locking jaw of the vertical driving cylinder to elastically support the vertical driving cylinder to maintain the vertical driving cylinder An elastic spring 1150 for supporting elevating and descending to enable it to be; It is inserted and coupled to the inner side of the up and down drive cylinder 1140, is generally cylindrical and consists of a plurality of drug passage holes 1161 installed on the bottom, and supplies drugs while flowing up and down according to the movement of the up and down drive cylinder. An odor drug applicator 1160; One side is coupled to the odor drug applicator 1160 and the other side is coupled to one end of the housing 1110, and the up and down driving cylinder and the odor drug applicator 1160 are temporarily fixed at the same time based on the housing to temporarily fix the odor drug applicator 1160. It is characterized by comprising a odor drug applicator temporary fixing means (1180) to prevent falling down by the action of gravity.

In addition, the odor drug applicator temporary fixing means 1180 is formed in a wedge shape with a sharp end, and is forcibly fitted through the coupling hole of the up and down driving cylinder and the coupling hole of the drug applicator, so that the odor drug applicator is A locking hook 1181 for maintaining a state coupled to the inner circumference; A connecting piece 1182 which is integrally connected to the hook for hook 1181 in a diagonal direction and guides the hook for hook 1181 to move in a clockwise or counterclockwise direction by a rotational motion; A hinge for supporting rotation (1183) installed between the connecting piece (1182) and the hook (1181) for supporting the connecting piece to rotate; It is installed between the connecting piece 1182 and the vertical driving cylinder 1140 to push the connecting piece outward so that the hook for locking 1181 flows counterclockwise to keep the drug applicator connected to the vertical driving cylinder. , When the connecting piece is pressed by an external force and compressed in the vertical driving cylinder direction, the hook for locking 1181 is separated from the vertical driving cylinder 1140 and the drug applicator 1160, and the drug applicator 1160 is a vertical driving cylinder. A support spring 1184 for guiding it to be removed from the 1140; A sliding flow piece (1185) installed at the end of the connecting piece (1182) and moving at the same time when the hook (1181) and the connecting piece (1182) move up and down according to the vertical flow of the vertical drive cylinder (1140); It is slidably coupled with the sliding fluid piece 1185 to support the vertical movement of the sliding fluid piece 1185, and when the odor drug applicator 1160 is replaced, the connecting piece 1182 is pushed in the vertical drive cylinder 1140 direction. As the connection piece 1182 is rotated around the hinge pin 1183 for rotation support by pressing, the hook for hook 1181 is separated from the vertical drive cylinder 1140 and the drug applicator 1160, and the odor drug applicator 1160 ) Is characterized in that it comprises a push button (1186) to induce removal from the vertical drive cylinder (1140).

The greenhouse according to the present invention can generate electricity from sunlight compared to a conventional greenhouse in which no solar cells are attached. In addition, it is possible to control the environment of a greenhouse such as cooling, heating or air conditioning with the generated power, and it can generate extra electricity. In addition, a greenhouse with a simple solar cell that does not have a function to control the wavelength incident to the greenhouse can generate power only, but the greenhouse according to the present invention can select and transmit a wavelength suitable for the growth of plants. By adjusting, the amount of sunlight can also be optimized. In addition, by using a translucent solar cell with uniform transmittance and transmission wavelength characteristics over the entire area, it is possible to provide a uniform sunlight condition in the greenhouse compared to the conventional translucent solar cells arranged with spaced apart cells. Simple and practical.

1 is a view showing a schematic view of a greenhouse using a translucent solar cell according to the present invention.
2 is a diagram showing an example of a light wavelength that varies depending on the dye used in the dye-sensitized solar cell.
3 is a view showing an example of a structure in which only a part of the outside is translucent solar cell in a greenhouse using a solar cell according to the present invention.
4 is a view showing an example of a greenhouse using both an opaque solar cell and a translucent solar cell in the greenhouse according to the present invention.
Figure 5 is a block diagram of the dust measuring means and the alarm signal output unit of the present invention.
6 is a conceptual diagram of an infrared transmitting means and an infrared receiving means constituting the dust measuring means of the present invention.
7 is a conceptual diagram of measuring dust using an infrared transmitting means and an infrared receiving means of the present invention.
Figure 8 is an exploded perspective view of the odor chemical application device of the present invention.
9 is a cross-sectional view and a cross-sectional view of the main part of the odor chemical application device of the present invention.
Figure 10 is an enlarged cross-sectional view of the main part of the odor chemical application device of the present invention.
11 is a configuration diagram of a rotary motor and a vertical drive cylinder of the odor chemical application device of the present invention.
12 is an enlarged view of the main parts of the rotating motor and the vertical drive cylinder of the odor chemical application device of the present invention.
13 is a block diagram of a temporary fixing means of the odor chemical application device of the present invention.
Figure 14 is another angular configuration of the temporary fixing means of the odor chemical application device of the present invention.
15 is a configuration diagram of a hole for passing a chemical solution according to the present invention.

Hereinafter, the operating principle of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings and the description to be described below are for a preferred implementation method among various methods for effectively describing the features of the present invention, and the present invention is not limited to the following drawings and description.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout the present invention.

In addition, a preferred embodiment of the present invention to be implemented below is already provided in each system function configuration in order to efficiently describe the technical components constituting the present invention, or system functions commonly provided in the technical field to which the present invention belongs. The configuration will be omitted as much as possible, and a functional configuration that should be additionally provided for the present invention will be mainly described.

If one of ordinary skill in the art to which the present invention pertains, among the functional configurations not shown below and omitted, the functions of the components already used in the past will be easily understood, and the configurations omitted as described above. The relationship between the elements and the elements added for the present invention will also be clearly understood.

In addition, in the following embodiments, terms will be appropriately modified and used so that those of ordinary skill in the art can clearly understand the key technical features of the present invention in order to efficiently describe the core technical features of the present invention. It is by no means limited.

As a result, the technical idea of the present invention is determined by the claims, and the following embodiments are one means for efficiently explaining the technical idea of the present invention to those of ordinary skill in the art to which the present invention belongs. It is only.

1 is a view showing a schematic view of a greenhouse using a translucent solar cell according to the present invention.

2 is a diagram showing an example of a light wavelength that varies depending on the dye used in the dye-sensitized solar cell.

3 is a view showing an example of a structure in which only a part of the outside is translucent solar cell in a greenhouse using a solar cell according to the present invention.

4 is a view showing an example of a greenhouse using both an opaque solar cell and a translucent solar cell in the greenhouse according to the present invention.

Figure 5 is a block diagram of the dust measuring means and the alarm signal output unit of the present invention.

6 is a conceptual diagram of an infrared transmitting means and an infrared receiving means constituting the dust measuring means of the present invention.

7 is a conceptual diagram of measuring dust using an infrared transmitting means and an infrared receiving means of the present invention.

Figure 8 is an exploded perspective view of the odor chemical application device of the present invention.

9 is a cross-sectional view and a cross-sectional view of the main part of the odor chemical application device of the present invention.

Figure 10 is an enlarged cross-sectional view of the main part of the odor chemical application device of the present invention.

11 is a configuration diagram of a rotary motor and a vertical drive cylinder of the odor chemical application device of the present invention.

Figure 12 is an enlarged view of the main portion of the rotary motor and the vertical drive cylinder of the odor chemical application device of the present invention.

13 is a block diagram of a temporary fixing means of the odor chemical application device of the present invention.

Figure 14 is another angular configuration of the temporary fixing means of the odor chemical application device of the present invention.

15 is a configuration diagram of a hole for passing a chemical solution of the present invention,

First, referring to FIG. 1, the outer wall of the greenhouse 100 is configured in a form in which a plurality of translucent solar cells 110 are arranged. The translucent solar cell 110 transmits only a specific wavelength of sunlight and generates solar power using sunlight of the remaining wavelengths that are not transmitted. Here, as the translucent solar cell 110, a dye-sensitized solar cell using a photoelectrochemical reaction may be used, or an amorphous silicon solar cell having a partially translucent property may be used by adjusting the thickness or area of the light absorbing layer. That is, any solar cell that has a translucent property and exhibits a property of partially transmitting light can be used in this embodiment. In addition, in the case of using the translucent solar cell 110 having a uniform transmittance and transmission wavelength characteristics over the entire area, it is possible to provide a uniform sunlight condition in a greenhouse compared to a solar cell arranged at an interval of cells. Since the outer wall of the greenhouse can be formed in various shapes using a curve or a straight line, it is preferable that the solar cell 110 is made of a flexible material and can be bent.

Here, unlike a wafer-type silicon or compound solar cell using a pn junction, the dye-sensitized solar cell receives light having a wavelength of visible light when it is incident and accepts dye molecules and excited electrons that can form electron-hole pairs. Its main constituents are oxide semiconductors and electrolytes that react with electrons that work and return to the battery. The dye-sensitized solar cell, which is well known so far, was announced by Grazel et al. of Switzerland. Photoelectrochemical solar cells published by Grachel et al. are photosensitive dye molecules capable of absorbing visible light to generate electron-hole pairs, and nanoparticles titanium dioxide (TiO ₂ ) on which dye molecules are adsorbed. It is composed of an oxide semiconductor electrode made of, a counter electrode coated with platinum or carbon, and an electrolyte solution filled therebetween. This photochemical cell has been attracting attention because its manufacturing cost per power is lower than that of a wafer-type solar cell using a pn junction.

In this way, in a dye-sensitized solar cell, the generation of electrons through absorption of light occurs in the dye, and the oxide semiconductor such as titanium dioxide used as an electrode simply moves the generated electrons to the current collector made of a conductor. It is possible to have it, and the wavelength band that is absorbed by the dye and generates electrons varies depending on what dye is used, so that the wavelength can be selected.

In addition, the transmittance can be easily adjusted by adjusting the type and concentration of dye adsorbed on the electrode or changing the type and thickness of the electrode layer. Even in an amorphous silicon solar cell using a transparent substrate such as glass, it can be manufactured in an overall translucent shape by adjusting the thickness of the absorbing layer through which light is absorbed or by arranging in a state with an interval between cells.

When a dye-sensitized solar cell is used as the translucent solar cell 110, the wavelength and transmittance of transmitted light are selected by controlling the type and concentration of the dye that absorbs light or the type and thickness of the electrode layer. That is, in the dye-sensitized solar cell 110, the transmitted wavelength can be controlled by simply changing the dye adsorbed on the oxide semiconductor such as TiO _2, and the transmittance is changed by different types and thickness of the electrode layer and the type and concentration of the dye. It is also possible to do. The wavelength used for power generation that generates electricity in a dye-sensitized solar cell may vary depending on the dye used.

For example, the translucent solar cell 110 uses light of a wavelength between 400 to 600 nm for solar power generation and transmits other wavelengths, or uses light of a wavelength between 600 to 800 nm for photovoltaic power generation. And it can be made to transmit wavelengths other than that. In addition, the translucent solar cell 110 may have a transmittance of less than 40% at a wavelength of 600 nm or a transmittance of 40% or more at a wavelength of 600 nm.

In the case of a greenhouse, the wavelength that must be transmitted varies depending on the type of plant grown. Table 1 shows the wavelength required for growth of each crop.

Wavelength (unit: nm) crops effect Red Light (660) Perilla leaves, chrysanthemum, strawberry Promote photosynthesis, control flowering Transcendental Life Light (730) Melon, tomato, ginseng Increased fruit tree, sugar content, and saponin Blue light (450) Vegetables, young seedlings Prevention of laughing out Green light (530) Cucumber and pepper Inhibits the occurrence of Gom Farm Yellow light (570) Apples, pears, peaches Pest control

Power is generated using light of a wavelength that is not beneficial to plants, and light of a wavelength that is beneficial to plants passes through the solar cell 110 and enters the greenhouse to grow plants. FIG. 2 is a dye-sensitized solar cell. A diagram showing an example of a light wavelength that varies depending on the dye used in FIG.

Referring to FIG. 2, it can be seen that a wavelength band in which quantum efficiency according to dye-A appears and a wavelength band in which quantum efficiency according to dye-B appears are different from each other. Dye A can be used in a situation where light of a wavelength between 400 and 600 nm is absorbed and used for solar power generation, and light of the rest of the wavelength must be transmitted, and Dye B is absorbed by light of a wavelength between 600 and 800 nm. It is used for power generation and can be used in situations in which light of the remaining wavelength must be transmitted. That is, by controlling the type and concentration of dyes used in solar cells, it is possible to change the transmitted wavelength.

3 is a view showing an example of a structure in which only a part of the outside of a greenhouse using a solar cell according to the present invention is formed of a semi-transparent solar cell.

Referring to FIG. 3, the greenhouse 300 constitutes an outer wall by mixing a transparent material 320 such as conventional glass and a translucent solar cell 310. Since the solar cell 310 does not constitute all the outside of the greenhouse 300, the amount of sunlight inside the greenhouse can be increased.

4 is a view showing an example of a greenhouse using both an opaque solar cell and a translucent solar cell in the greenhouse according to the present invention.

Referring to FIG. 4, the outside of the greenhouse 400 is composed of an opaque solar cell 420 and a translucent solar cell 410. The opaque solar cell 420 and the translucent solar cell 410 may be arranged in a zigzag shape or in various arrangements according to the amount of sunlight required inside the greenhouse.

On the other hand, the present invention is installed by adding a dust measuring means (1000a) to one side of the inside of the greenhouse, and when it is determined that there is dust above the standard as a result of the measurement by the dust measuring means (1000a), an alarm signal is transmitted through the alarm signal output means. Print them out and induce them to stop outdoor activities.

The dust measuring means (1000a) of the present invention includes a wire mesh (10a) that removes moisture from input dust and guides only the correct dust to pass, and a rotary motor (10b) for accelerating the removal of moisture existing in the air by rotating the wire mesh. ), and an electric means for providing heater heat (10c) for supplying heat to the wire mesh to evaporate moisture in contact with the wire mesh at a high speed, and infrared transmission for emitting infrared rays to detect dust passing through the wire mesh. Means (A), and an infrared receiving means (B) positioned to face the infrared transmitting means and configured to receive light emitted from the infrared transmitting means and to determine the inflow of dust according to the degree of the received amount, and the infrared When the output voltage of the receiving means (B) is less than the set value, it includes a dust measurement control unit (C) for controlling the input voltage of the infrared transmitting means (A) to increase.

Further, the infrared transmission means (A) receives the infrared transmission control signal from the dust measurement control unit (C), determines the infrared transmission amount, and outputs the changed infrared transmission amount.

That is, when the result value of the infrared receiving means (B) is transmitted to the dust measurement control unit (C), the dust measurement control unit (C) predicts the amount of dust generated based on the data of the infrared receiving unit (B), and By outputting a control signal to the infrared transmission means (A), the amount of infrared transmission is adjusted to induce output.

In other words, the dust measurement control unit reads the light quantity data output from the infrared receiving means, and based on this, the light quantity of the infrared light emitting means is automatically controlled so that the sensitivity control is automatically kept constant. It is designed to be able to measure by maintaining it in a sensitivity state.

In other words, if the amount of light received by the infrared receiver (B) is weak, the dust measurement control unit (C) determines that the degree of contamination is high, and outputs a control signal to increase the amount of light from the infrared transmitter (A) for more precise dust measurement. And, if the amount of received light of the infrared receiving means (C) is too much, the state without contamination or precise measurement becomes difficult, so that a control signal is output to reduce the amount of light of the infrared transmitting means (A). That is, it is necessary to maintain the amount of infrared light transmitted in an appropriate state. Only then can the amount of infrared rays measured through the infrared receiving means become accurate, so that the amount of dust generated can be more accurately predicted. Accordingly, the dust amount data measured by the dust measurement control unit of the present invention can output a dust measurement result with high reliability.

On the other hand, the present invention is provided with an odor chemical liquid coating device 1100 as an alarm signal output means, if fine dust is above the standard, the odor is output from the odor chemical liquid application device 1100 to force the operator to move away from the device.

That is, it is electrically connected to the dust measuring means (1000a) and further comprises a odor chemical application device that applies odor to the outside according to the control signal of the dust measuring means, and if fine dust is above the standard, in order to protect the worker It is to output the odor.

The odor chemical application device 1100 includes a housing 1110, a battery 1120, a rotary motor 1130, an up and down drive cylinder 1140, an elastic spring 1150 for lifting and lowering support, and an odor drug applicator. It consists of (1160), a chemical liquid storage means (1170), and an applicator temporary fixing means (1180).

The housing 1110 has a space therein, and is formed by embedding various devices. That is, the housing is configured by bonding two cases with one side open to each other, and various devices are installed in a space portion generated in the process of bonding the cases. Such a housing is generally of a structure similar to the means having a space therein.

The battery 1120 is installed inside the housing 1110 and serves to supply electricity to the device after charging electricity by receiving power from the outside. That is, the battery is installed on the upper part of the housing and is electrically connected to an external power supply to receive electricity, and temporarily stores the supplied power to supply electricity to various devices that require power.

The rotary motor 1130 is electrically connected to a battery and receives power from the battery and converts it into a mechanical rotational motion to freely rotate the motor shaft. At this time, the motor shaft 1131 has a shape in which a bottom surface is formed in a waveform shape in a vertical direction so that a curved waveform shape continuously rotates. That is, the rotary motor rotates by receiving power from a battery, and the bottom surface of the motor shaft is formed in a curved waveform to rotate.

The vertical drive cylinder 1140 is mechanically connected to the rotary motor, but is moved while moving up and down by converting the rotation of the rotary motor into a reciprocating vertical motion. At this time, the rotation shaft 1141 of the vertical drive cylinder 1140 has an upper surface in a shape of a waveform in a vertical direction, and moves up and down while repeating mutual coupling and separation with the waveform of the motor shaft of the rotary motor. In other words, the vertical driving cylinder is formed in the form of a curved waveform in the same way as the motor shaft of the rotating motor so that the vertical movement is performed according to the rotation of the rotating motor, and accordingly, when the rotating motor rotates, the vertical driving cylinder moves up and down. Will do.

The lifting and lowering support elastic spring 1150 is installed on the outer periphery of the vertical driving cylinder 1140, but one side is fixed to the locking jaw inside the housing 1110 and the other side is fixed to the locking jaw of the vertical driving cylinder 1140 The vertical driving cylinder 1140 is elastically supported so that the vertical driving cylinder 1140 can maintain the lifting operation. That is, since the elastic spring 1150 for elevating and descending supports the elasticity of continuously pushing the vertical drive cylinder 1140 upward, the waveform of the motor shaft 1131 of the rotary motor and the The vertical drive cylinder descends as the waveforms of the rotation shaft 1141 of the vertical drive cylinder 1140 are staggered, and after the staggering is over, the vertical drive cylinder 1140 rises by the elastic spring 1150 for lifting and lowering support. The waveform of 1141 and the waveform of the motor shaft 1131 of the rotary motor 1130 are in close contact. Accordingly, the vertical driving cylinder 1140 is repeatedly close to and spaced apart from the rotary motor 1130, so that the vertical driving cylinder 1140 continuously moves vertically around the rotary motor 1130.

The odor drug applicator 1160 has a body cylinder shape and has a plurality of odor drug passage holes 1161 installed on the bottom surface, is inserted and coupled to the inside of the up and down drive cylinder 1140, and supplies odor drugs. Plays a role. That is, the odor drug applicator 1160 allows the odor drug stored therein to be discharged to the outside through the odor drug passage hole 1161, and at this time, the odor drug applicator 1160 is installed inside the vertical driving cylinder. Therefore, when the vertical driving cylinder 1140 is operated up and down, the odor drug applicator 1160 is hit, and the drug is output to the outside according to the law of inertia.

The odor drug storage means 1170 is in a state in which the odor drug is accommodated, and is inserted and installed in the odor drug applicator 1160 to be output through the odor drug passage hole 1161 of the odor drug applicator 1160. . That is, the malodor chemical liquid storage means 1170 is in a state in which the drug is stored, and the lower part is coupled to the malodor drug applicator 1160 in an open form, and when the vertical drive cylinder 1140 is driven, the malodor of the malodor chemical liquid storage means The drug is output to the outside. In fact, since the odor drug passage hole 1161 is formed finely, it is not easily discharged to the outside when the vertical drive cylinder 1140 is not operated.

The odor drug applicator temporary fixing means 1180 has one side coupled to the odor drug applicator 1160 and the other side coupled to one end of the housing 1110, and a vertical driving cylinder 1140 based on the housing 1110 and By temporarily fixing the odor drug applicator 1160 at the same time, the up and down driving cylinder 1140 and the odor drug applicator 1160 flow up and down while preventing the odor drug applicator 1160 from falling down due to gravity When replacing the odor drug applicator 1160, the odor drug applicator is released from the vertical drive cylinder by pressing the button to release the fixation of the odor drug applicator based on the housing so that the odor drug applicator is separated from the vertical driving cylinder and removed downward. That is, the odor drug applicator temporary fixing means prevents the odor drug applicator from being removed during operation by temporarily fixing the up and down driving cylinders and the odor drug applicator, and after using all the drugs existing inside the odor drug applicator, the button After releasing the odor drug applicator by pressing, the odor drug storage means is induced to be re-stored.

The temporary fixing means 1180 includes a hook for locking 1181, a connecting piece 1182, a hinge for rotation support 1183, a spring for support 1184, a sliding piece 1185, and a push button 1186).

The hook for hook 1181 is formed in a wedge shape with a sharp end and is forcibly fitted through the coupling hole 1140a of the vertical drive cylinder 1140 and the coupling hole 1160a of the drug applicator 1160 to apply odor drugs. The machine 1160 maintains a state coupled to the inner periphery of the vertical drive cylinder 1140.

The connecting piece 1182 is integrally connected to the locking hook 1181 in a diagonal direction, and induces the locking hook 1181 to move in a clockwise or counterclockwise direction by a rotational motion.

The rotation support hinge 1183 is installed between the connecting piece 1182 and the hook 1181 for locking, and serves as a central axis through which the connecting piece is rotated.

The support spring 1184 is installed between the connecting piece 1182 and the vertical driving cylinder 1140 to push the connecting piece outward so that the locking hook 1181 flows in a counterclockwise direction, so that the drug applicator is coupled to the vertical driving cylinder. It functions to maintain the state, and when the connecting piece is pressed by an external force and is compressed in the vertical driving cylinder direction, the hook for locking 1181 is separated from the vertical driving cylinder 1140 and the odor drug applicator 1160, Induces the applicator 1160 to be removed from the vertical drive cylinder 1140.

The sliding flow piece 1185 is installed at the end of the connecting piece 1182 and moves simultaneously when the hook for locking 1181 and the connecting piece 1182 move up and down according to the up and down flow of the up and down driving cylinder 1140.

The push button 1186 is slidably coupled with the sliding fluid piece 1185 to support the vertical movement of the sliding fluid piece 1185, and when the odor drug applicator 1160 is replaced, it moves in the vertical direction cylinder 1140 By pushing and pressing the connecting piece 1182, the connecting piece 1182 rotates around the hinge pin 1183 for rotation support, so that the hook for locking 1181 is moved up and down from the cylinder 1140 and the odor drug applicator 1160. As it is separated, it serves to induce the odor drug applicator 1160 to be removed from the vertical driving cylinder 1140.

100: greenhouse
110: translucent solar cell

Claims (4)

A translucent solar cell installed on the outer wall of the greenhouse, which transmits a specific wavelength of light and generates solar power using light of the remaining wavelengths that are not transmitted;
A dust measuring means installed at one end of the greenhouse to measure dust and output an alarm signal if it is above a standard;
Consisting of including an odor application device that is electrically connected to the dust measuring means and outputs odor to the outside according to a control signal of the dust measuring means
The translucent solar cell is a dye-sensitized solar cell, and a greenhouse using a translucent solar cell, characterized in that light of a wavelength of 400 to 600 nm or light of a wavelength of 600 to 800 nm is used for solar power generation. The method of claim 1,
The dust measuring means,
A wire mesh (10a) that removes moisture from dust and guides only the correct dust to pass through, a rotary motor (10b) for accelerating the removal of moisture existing in the air by rotating the wire mesh, and supplies heat to the wire mesh to the wire mesh. Electric means (10c) for providing heater heat for evaporating contacted moisture at a high speed, infrared transmission means (A) for emitting infrared rays to detect dust passing through the wire mesh, and facing the infrared transmission means Infrared receiving means (B) for receiving light emitted from the infrared transmitting means and determining dust inflow according to the degree of the received amount, and the output voltage of the infrared receiving means (B) is higher than a set value. A greenhouse using a translucent solar cell, comprising: a dust measurement control unit (C) for controlling the input voltage of the infrared transmission unit (A) to increase. The method of claim 1,
The odor application device 1100,
A housing 1110;
A battery 1120 installed inside the housing 1110 and receiving power from the outside to charge electricity and then supply electricity to the device;
A rotary motor (1130) electrically connected to the battery to receive power from the battery and convert it into a mechanical rotary motion;
A motor shaft (1131) installed on the central axis of the rotary motor to rotate in response to the rotation of the rotary motor, but having a bottom surface in a waveform shape and continuously rotating in a curved waveform shape;
A vertical driving cylinder 1140 located at the lower end of the rotating motor and flowing while moving up and down by converting the rotation of the rotating motor into a reciprocating vertical motion;
It is located above the vertical drive cylinder 1140, but is located on the central axis, and is mechanically contacted while being in contact with the motor shaft 1131 of the rotary motor 1130, and is coupled with the motor shaft 1131 of the rotary motor 1130. And a rotation shaft 1141 for elevating and descending while repeating the separation.
Installed on the outer periphery of the vertical driving cylinder 1140, one side is fixed to the locking jaw inside the housing and the other side is fixed to the locking jaw of the vertical driving cylinder to elastically support the vertical driving cylinder to maintain the vertical driving cylinder An elastic spring 1150 for supporting elevating and descending to enable it to be;
It is inserted and coupled to the inner side of the up and down drive cylinder 1140, is generally cylindrical and consists of a plurality of drug passage holes 1161 installed on the bottom, and supplies drugs while flowing up and down according to the movement of the up and down drive cylinder. An odor drug applicator 1160;
One side is coupled to the odor drug applicator 1160 and the other side is coupled to one end of the housing 1110, and the up and down driving cylinder and the odor drug applicator 1160 are temporarily fixed at the same time based on the housing to temporarily fix the odor drug applicator 1160. A greenhouse using a translucent solar cell, characterized in that it comprises a odor drug applicator temporary fixing means (1180) to prevent falling down due to gravity action. The method of claim 1,
The odor drug applicator temporary fixing means 1180,
A hook for locking (1181) that has a sharp wedge-shaped end and is forcibly fitted through the coupling hole of the vertical drive cylinder and the coupling hole of the drug applicator to keep the odor drug applicator connected to the inner periphery of the vertical drive cylinder. Wow;
A connecting piece 1182 which is integrally connected to the hook for hook 1181 in a diagonal direction and guides the hook for hook 1181 to move in a clockwise or counterclockwise direction by a rotational motion;
A hinge for supporting rotation (1183) installed between the connecting piece (1182) and the hook (1181) for supporting the connecting piece to rotate;
It is installed between the connecting piece 1182 and the vertical driving cylinder 1140 to push the connecting piece outward so that the hook for locking 1181 flows counterclockwise to keep the drug applicator connected to the vertical driving cylinder. , When the connecting piece is pressed by an external force and compressed in the vertical driving cylinder direction, the hook for locking 1181 is separated from the vertical driving cylinder 1140 and the drug applicator 1160, and the drug applicator 1160 is a vertical driving cylinder. A support spring 1184 for guiding it to be removed from the 1140;
A sliding flow piece (1185) installed at the end of the connecting piece (1182) and moving at the same time when the hook (1181) and the connecting piece (1182) move up and down according to the vertical flow of the vertical drive cylinder (1140);
It is slidably coupled with the sliding fluid piece 1185 to support the vertical movement of the sliding fluid piece 1185, and when the odor drug applicator 1160 is replaced, the connecting piece 1182 is pushed in the vertical drive cylinder 1140 direction. By pressing, the connecting piece 1182 rotates around the hinge pin 1183 for rotation support, and the hook 1181 is separated from the vertical drive cylinder 1140 and the drug applicator 1160, and the odor drug applicator 1160 ) Is a greenhouse using a translucent solar cell, characterized in that it comprises a push button (1186) to induce removal from the vertical drive cylinder (1140).

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