Patent Description:
<CIT> illustrates, for example, an alternative plant cultivation apparatus.

A plant cultivation apparatus refers to an apparatus capable of plant cultivation by artificially supplying light energy, moisture, soil, and temperature necessary for plant growth. The plant cultivation apparatus has a predetermined cultivation space defined therein having an environment suitable for plant growth, and cultivates and stores the plant in the predetermined cultivation space.

Further, the plant cultivation apparatus may include components for supplying moisture and nutrients necessary for plant growth. Further, the plant cultivation apparatus may include a component for artificially supplying light energy. Thus, the plant cultivated in the plant cultivation apparatus may be artificially supplied with light energy from the plant cultivation apparatus while not receiving light irradiated from the sun outside the plant cultivation apparatus.

Accordingly, a user may not periodically supply moisture or nutrient in a cultivation operation process of the plant. The plant cultivated in the plant cultivation apparatus grows upon receiving the nutrient, moisture and light energy supplied from the plant cultivation apparatus.

A water-based cultivation scheme as one of schemes for cultivating a plant refers to a scheme for cultivating a plant by supplying to the plant a cultivation medium in which inorganic nutrients necessary for growth are dissolved in water, instead of using soil. The water-based cultivation scheme is more hygienic than the soil-based cultivation scheme using soil is, and is less affected by weather and season. Thus, the water-based cultivation scheme may create a more favorable growth condition than the soil-based cultivation scheme may.

Further, a hydroponic water-based cultivation scheme as one of the water-based cultivation schemes refers to a cultivation scheme in which the plant is cultivated so that the roots thereof are received in nutrient liquid and a stem and leaves of the plant are grown in a space above the nutrient liquid.

In this hydroponic water-based cultivation scheme, the nutrient liquid containing nutrients therein is stored in a storage tank, and the nutrient liquid is supplied to a pod where the plant is cultivated, so that the plant is grown while the plant's roots are received in the nutrient liquid.

However, a required nutrient amount increases according to a growth period of the plant, and a required nutrient amount varies based on a plant type.

In particular, for special plants among plant types, a nutrient concentration should be controlled based on growth periods. For plants such as fruits and vegetables, the nutrient concentration should be controlled such that a growth state changes from vegetative growth to reproductive growth. Thus, it causes inconvenience for the user to additionally control the nutrient concentration based on plant types to be cultivated and based on growth stages.

Therefore, it is an important task in the present technical field to design a structure that additionally supplies the nutrients based on the type of the plant and the growth stages using water supplied from the storage tank to the pod.

The invention is achieved with the appended claims.

Embodiments of the present disclosure are to provide a plant cultivation apparatus that may additionally supply nutrients based on a type of a plant or growth stages.

Further, embodiments of the present disclosure are to provide a plant cultivation apparatus having a cultivator including a nutrient feeder in which nutrient for the plant is received, thereby improving convenience of a user.

Further, embodiments of the present disclosure are to provide a plant cultivation apparatus in which a water supply for supplying water to a cultivator supplies water to a nutrient feeder in which nutrient for the plant is received such that the nutrient is fed thereto.

Further, embodiments of the present disclosure are to provide a plant cultivation apparatus in which a vertical level of a water surface inside a cultivator may vary to supply water to a nutrient feeder such that the nutrient for the plant is supplied to a cultivation medium.

Further, embodiments of the present disclosure are to provide a plant cultivation apparatus that may have an additional supply channel for supplying water to a nutrient feeder, wherein the additional supply channel may supply water to the nutrient feeder such that the nutrient for the plant is fed to the plant.

In order to achieve the purposes, embodiments of the present disclosure provide a plant cultivation apparatus including a cultivator and a nutrient feeder disposed in a cultivator to receive therein the nutrient for the plant.

Specifically, a plant cultivation apparatus according to an embodiment of the present disclosure includes a cabinet, a bed, a cultivator, and a water supply. The bed is disposed inside the cabinet. The cultivator is seated on the bed and is constructed to receive therein a cultivation medium containing therein at least a portion of the plant. The water supply is disposed inside the cabinet and is configured to supply water to the cultivator.

Further, the cultivator includes a cultivation vessel and a nutrient feeder. the cultivation vessel is seated on the bed, and has a cultivation medium receiving space defined therein in which the cultivation medium is received. The nutrient feeder is disposed in the cultivation medium receiving space, and the nutrient for the plant is received in the nutrient feeder.

Further, the cultivation vessel may be constructed such that water supplied from the water supply is stored in the cultivation medium receiving space and is then provided to the cultivation medium, and the nutrient feeder may be spaced apart from a bottom surface of the cultivation vessel.

Further, the nutrient feeder may be constructed such that when the nutrient feeder comes into contact with the water stored in the cultivation medium receiving space, the nutrient therein is mixed with the water to produce a mixed solution which in turn is provided to the cultivation medium.

In the plant cultivation apparatus according to one embodiment of the present disclosure, the cultivation vessel may have a first communication hole defined therein for receiving water from the water supply. The water supply may include a first water supply channel disposed in the bed for supplying water to the cultivation medium receiving space through the first communication hole.

Further, the nutrient feeder may have a nutrient feeding hole defined therein communicating with the cultivation medium receiving space. The plant cultivation apparatus according to an embodiment of the present disclosure may be configured such that when the water stored in the cultivation medium receiving space flows into the nutrient feeder, a mixed solution of the nutrient and the water is discharged through the nutrient feeding hole.

The cultivation vessel has an open top so that the cultivation medium receiving space is exposed outwardly through the open top. The cultivator further includes a cover and a cover channel.

Further, the cover is disposed on the open top of the cultivation vessel to block the cultivation medium receiving space. The cover channel is defined in a top face of the cover and receive the water supplied from the water supply.

Further, the cover channel has a first inflow hole communicating with the inside of the nutrient feeder, wherein water is supplied to the nutrient feeder through the first inflow hole.

Further, the cover channel may be defined by recessing a portion of the top face of the cover, wherein the cover includes a cultivation medium receiving portion receiving an upper end of the cultivation medium in the cultivation medium receiving space, wherein the cultivation medium receiving portion is disposed in the cover channel and protrudes upwards from a bottom surface of the cover channel.

Further, the first inflow hole may be defined so as to be in contact with the bottom surface of the cover channel. Water received in the cover channel may flow into the nutrient feeder through the first inflow hole.

Further, the nutrient feeder may be configured to protrude upward from the bottom surface of the cover channel and be spaced apart from the cultivation medium receiving portion. The plurality of first inflow holes may be arranged along the circumference of the nutrient feeder. That is, the first inflow holes are arranged around the nutrient feeder.

The nutrient feeder has a nutrient feeding hole defined therein in communication with the cultivation medium receiving space, wherein the nutrient feeder has a side face extending from the cover toward the bottom surface of the cultivation vessel, and a bottom portion connected to the side face, wherein the nutrient feeding hole defined in the bottom portion.

Further, the first inflow hole extends through the side face and communicates with the inside of the nutrient feeder.

Further, the water supply further includes a second water supply channel at least partially located above the cover channel to supply water to the cover channel, wherein water supplied from the second water supply channel to the cover channel flows through the first inflow hole and into the nutrient feeder.

The apparatus further comprises a controller disposed in the cabinet and configured to control the water supply.

In a general mode, the controller is configured to control the water supply to supply water to the cultivation medium receiving space through the first water supply channel such that a vertical level of a water-surface in the cultivation medium receiving space is lower than a vertical level of the nutrient feeding, thereby preventing inflow of water into the nutrient feeder.

Further, in an additional water supply mode, the controller is configured to control the water supply to supply water to the cultivation medium receiving space through the first water supply channel such that a vertical level of the water-surface in the cultivation medium receiving space is higher than or equal to the vertical level of the feeding hole such that the nutrient of the nutrient feeder is mixed with the water to produce the mixed solution to be fed to the medium.

Further, the water supply is configured to supply water to the cultivator selectively through one of the first water supply channel and the second water supply channel.

Further, in the general mode, the controller is configured to control the water supply to block the second water supply channel and to supply water to the cultivation medium receiving space through the first water supply channel.

Further, in an upper water supply mode, the controller is configured to control the water supply to block the first water supply channel and to supply water to the cover channel through the second water supply channel.

Further, in the upper water supply mode, the controller is configured to control the water supply such that water is supplied from the cover channel to the nutrient feeder, and thus a mixture of water and the nutrient from the nutrient feeder is supplied to the cultivation medium.

The features of the above-described embodiments may be implemented in combination with those of other embodiments unless contradictory or exclusive to those of the other embodiments.

Embodiments of the present disclosure may realize a plant cultivation apparatus that may additionally supply nutrients based on a type of a plant or growth stages.

Further, embodiments of the present disclosure may realize a plant cultivation apparatus having a cultivator including a nutrient feeder in which nutrient for the plant is received, thereby improving convenience of a user.

Further, embodiments of the present disclosure may realize a plant cultivation apparatus in which a water supply for supplying water to a cultivator supplies water to a nutrient feeder in which nutrient for the plant is received such that the nutrient is fed thereto.

Further, embodiments of the present disclosure may realize a plant cultivation apparatus in which a vertical level of a water surface inside a cultivator may vary to supply water to a nutrient feeder such that the nutrient for the plant is supplied to a cultivation medium.

Further, embodiments of the present disclosure may realize a plant cultivation apparatus that may have an additional supply channel for supplying water to a nutrient feeder, wherein the additional supply channel may supply water to the nutrient feeder such that the nutrient for the plant is fed to the plant.

Effects of the embodiments of the present disclosure are not limited to those as described above, and other effects as not mentioned above may be clearly recognized by those skilled in the art based on following descriptions.

The same reference numbers may be allocated to the same or similar components. Redundant descriptions thereof will be omitted. As used herein, a suffix "module" or "unit" as used for a component are intended only for ease of describing the present disclosure, and the suffix "module" or "unit" itself does not have a specific meaning or role. Furthermore, in the following detailed description of the present disclosure, numerous specific details are set forth in order to provide a thorough understanding of the present disclosure. However, it will be understood that the present disclosure may be practiced without these specific details. In other instances, well-known methods, procedures, components, and circuits have not been described in detail so as not to unnecessarily obscure aspects of the present disclosure. Examples of various embodiments are illustrated and described further below. It will be understood that the description herein is not intended to limit the claims to the specific embodiments described. On the contrary, it is intended to cover alternatives, modifications, and equivalents as may be included within the scope of the present disclosure as defined by the appended claims.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the present disclosure. It will be further understood that the terms "comprises", "comprising", "includes", and "including" when used in this specification, specify the presence of the stated features, integers, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, operations, elements, components, and/or portions thereof. Expression such as "at least one of" when preceding a list of elements may modify the entirety of list of elements and may not modify the individual elements of the list. When referring to "C to D", this means C inclusive to D inclusive unless otherwise specified.

<FIG> is a perspective view of a plant cultivation apparatus <NUM> according to one embodiment of the present disclosure. <FIG> is a perspective view of a state in which a door <NUM> is opened in the plant cultivation apparatus <NUM> according to one embodiment of the present disclosure.

As shown in <FIG> and <FIG>, the plant cultivation apparatus <NUM> according to one embodiment of the present disclosure includes a cabinet <NUM> having a cultivation space S1 defined therein in which a plant is cultivated, and the door <NUM> for opening and closing the cabinet <NUM>. An outer appearance of the apparatus <NUM> may be defined by the cabinet <NUM> and the door <NUM>. The plant cultivated in the cultivation space S1 may be of a type of a plant that may be eaten by a user, may be easily cultivated, and may not occupy a lot of space, such as leafy vegetables and herbs.

The cabinet <NUM> may have one open face having an opening defined therein. The cultivation space S1 may be defined in the cabinet <NUM>. The cabinet <NUM> may have a rectangular parallelepiped shape as shown in the drawing, but is not necessarily limited thereto. The cabinet <NUM> may be formed in various forms such as a cylinder and a sphere as long as the cultivation space S1 may be defined therein. Further, as shown in <FIG> and <FIG>, the door <NUM> may be sized to shield the opening of the cabinet <NUM>. Hereinafter, for convenience of descriptions, the open face defines a front face of the cabinet <NUM>. However, the disclosure is limited thereto.

The door <NUM> may have a door panel <NUM> which is at least partially transparent. The door panel <NUM> may be made of a glass or a transparent plastic material such that the user may see through the panel <NUM> into an inside of the cabinet.

Due to this structure, the user may visually identify the inside of the cultivation space S1 even when the door <NUM> is closed, so that a growth state of the plant may be identified by the user. Further, interior effects may be derived. When the identification of the inside of the cabinet is unnecessary, a neat outer appearance of the apparatus may be maintained.

In some cases, a colored coating or a vapor deposited film may be attached to the door panel <NUM>. Thus, the panel <NUM> may be constructed such that the cultivation space S1 is selectively visible or invisible to the user.

In one example, the door <NUM> may include a door frame <NUM> that constitutes a perimeter of the door. A central portion of the door frame <NUM> may be opened to define an opening. The door panel <NUM> may be constructed to shield the opening of the door frame <NUM>.

Further, the door <NUM> may include a door sealing <NUM> disposed on one face of the door frame <NUM> facing toward the cabinet <NUM> and disposed along a perimeter of the opening of the door frame <NUM>. The door sealing <NUM> may absorb an impact force exerted from the door <NUM> onto the cabinet <NUM> when the door <NUM> is closed, thereby improving durability and reliability of the plant cultivation apparatus <NUM>. Further, the door sealing <NUM> may prevent air flow from the cultivation space S1 and the cabinet <NUM> to the outside so that a temperature and a humidity of the cultivation space S1 may be kept constant. Further, the door sealing <NUM> may be made of an insulating material so that the cabinet <NUM> may be thermally insulated. Accordingly, the cultivation space S1 may maintain a temperature thereof set by the user.

In one example, the door <NUM> may have a door coupler <NUM> disposed on one side of the door frame <NUM> and coupled to the cabinet <NUM>. As shown in <FIG> and <FIG>, the door coupler <NUM> may be disposed on one side of left and right sides of the door frame <NUM>. Accordingly, the door may be opened and closed in one direction of left and right directions around the user, thereby increasing the user's convenience. Further, the door <NUM> may be pivotably coupled to the cabinet <NUM> via the door coupler <NUM>. The cultivation space S1 may be opened and closed according to pivoting of the door <NUM>. Further, the door <NUM> may have a door handle <NUM> disposed at one of an upper end and a lower end of the door frame <NUM>. The user may hold the handle <NUM> to open and close the door <NUM>. When the door coupler <NUM> is disposed on one side of the left and right sides of the door frame <NUM>, the door handle <NUM> may be disposed on the other side of the left and right sides of the door frame <NUM>.

In one example, a lower cabinet <NUM> may constitute a bottom portion of the cabinet <NUM>. The lower cabinet <NUM> may receive an air adjuster (not shown) therein that receives outside-air and supplies the outside-air to the cultivation space S1.

In the plant cultivation apparatus <NUM> according to an embodiment of the present disclosure, a plurality of beds <NUM> may be vertically arranged inside the cabinet <NUM>. In the plant cultivation apparatus <NUM> according to the embodiment of the present disclosure, two beds <NUM> may be respectively disposed in an upper portion and a lower portion of the cabinet <NUM>. Hereinafter, for convenience of description and understanding, the two beds <NUM> may be referred to as an upper bed <NUM> and a lower bed <NUM>, respectively. In another example, at least three beds <NUM> may be arranged depending on a size of the cabinet <NUM>.

Further, a plurality of cultivators <NUM> containing plant seeds and nutrients required for cultivation may be seated on a top face of the bed <NUM>. Thus, the bed <NUM> may be referred to as a shelf or a tray. The interior of the cabinet <NUM> may act as the cultivation space S1 in which the plant is cultivated.

The cultivator <NUM> may be provided to be adapted to a combination of various kinds of seeds and corresponding nutrients. The user may select the cultivator to be adapted to a target plant type for cultivation. Further, the bed <NUM> may have a structure on which the cultivator <NUM> may be seated and by which a seating state thereof may be maintained.

Further, as will be described later, the bed <NUM> may have a communication channel <NUM> defined therein through which water supplied from a water supply <NUM> flows. Further, the bed <NUM> may maintain an adequate water-level therein so that water may be supplied to the cultivator <NUM> at all times.

<FIG> is a perspective view showing a state in which a cultivator according to one embodiment is seated on a bed in a plant cultivation apparatus according to an embodiment of the present disclosure.

<FIG> shows the bed <NUM>, the water supply <NUM>, and the cultivator <NUM> disposed inside the cabinet <NUM> in the plant cultivation apparatus <NUM> according to one embodiment of the present disclosure.

The plant cultivation apparatus <NUM> according to one embodiment of the present disclosure may include the bed <NUM> disposed inside the cabinet, the cultivator <NUM> seated on the bed and receiving therein a cultivation medium <NUM> in which at least a portion of the plant is received, and the water supply <NUM> disposed inside the cabinet and configured to supply water to the bed <NUM>.

The water supply <NUM> may include a water supply casing <NUM> having storage (not shown), a supply pump (not shown), a flow sensor (not shown), a branching valve (not shown), and a connective channel (not shown) as described below received therein.

The storage (not shown) may store therein water to be supplied to the cultivator <NUM> for the plant.

As shown in <FIG>, the water supply casing <NUM> may be disposed below the bed and may be coupled to the cabinet <NUM>.

Due to the water supply casing <NUM>, the storage (not shown), the supply pump (not shown), the flow sensor (not shown), the branching valve (not shown), and the connective channel (not shown) are not exposed to the outside, thereby improving the reliability of supply <NUM>, and achieving neat outer appearance.

In one example, the cultivator <NUM> may be seated on the bed. The nutrient liquid (hereinafter, water) from the water supply <NUM> may be fed to the cultivator <NUM> through the communication channel <NUM> which will be described later. The cultivator <NUM> may be constructed such that the water may be discharged to the storage (not shown) through the communication channel <NUM>.

Further, the cultivator <NUM> may include a plurality of cultivators disposed on a top face of the bed <NUM>. Thus, the plurality of cultivators <NUM> may receive different types of plants, respectively. Thus, the different types of plants may be cultivated in the cultivation space S1.

In other words, the cultivator <NUM> may be provided to be adapted to a combination of various kinds of seeds and corresponding nutrients. The user may select a plant to be cultivated and cultivate the plant in the cultivator <NUM>.

Further, the cultivator <NUM> may be removably seated on the bed <NUM>. Accordingly, the user may input the cultivation medium <NUM> containing the seeds of the plant therein into the cultivator <NUM> while the cultivator <NUM> is located out of the plant cultivation apparatus <NUM>. Then, the user may seat the cultivator <NUM> on the bed <NUM> through one open face of the cabinet <NUM>.

Further, when the plant grows and then a harvest timing arrives, the user may separate the cultivator <NUM> from the bed <NUM>. Thus, the plant in the cultivator <NUM> may be easily harvested while the cultivator is located out of the plant cultivation apparatus <NUM>, thereby increasing easiness and convenience of harvesting by the user.

Further, the cultivator <NUM> may have a shape extending from one side thereof to the opposite side thereof. A direction in which the cultivator <NUM> extends may be a first direction from the cultivation space S1 toward the door <NUM>.

Further, as shown, while being seated on the top face of the bed <NUM>, the plurality of cultivators <NUM> may be arranged to be spaced apart from each other in the first direction in which the cultivator <NUM> extends and a second direction perpendicular to the first direction.

Hereinafter, for convenience of description, a direction in which the cultivator <NUM> extends is defined as the first direction, while a direction perpendicular to the first direction is defined as the second direction.

In one example, the bed <NUM> may be embodied as a rectangular plate that partitions an inside of the cabinet <NUM>. Although not shown in the drawing, the bed <NUM> may be seated into a retract and extend guide (not shown) defined in each of both opposing side faces of the cabinet <NUM> in the retracting and extending manner.

A bed water collector <NUM> constructed to receive water through the water supply <NUM> may be formed in one side of the bed <NUM>. The bed water collector <NUM> may be connected to the communication channel <NUM> disposed inside the bed <NUM>, such that the water supplied to the bed water collector <NUM> may be continuously supplied to the cultivator <NUM>.

The water supply <NUM> may include a first upper supply channel51 extending to the bed water collector <NUM> of the upper bed <NUM> and a first lower supply channel52 extending to the bed water collector <NUM> of the lower bed <NUM>. The first upper supply channel51 and the first lower supply channel52 may be configured to supply the water to the upper bed <NUM> and the lower bed <NUM>, respectively. The water supply <NUM> may have water discharge holes <NUM> and <NUM> defined respectively at positions corresponding to the bed water collectors <NUM>. Thus, the water supplied from the first upper supply channel51 and the first lower supply channel52 may be directly inflowed to the bed water collectors <NUM>.

Each of the first upper supply channel51 and the first lower supply channel52 may be embodied as a metal pipe made of stainless steel. Thus, each of the first upper supply channel51 and the first lower supply channel52 may be managed hygienically and may be maintained in a rigid manner to prevent clogging thereof due to deformation or bending of a flow path, and to improve the reliability of water supply.

A water supply structure in which the water is fed to the upper bed <NUM> and a water supply structure in which the water is fed to the lower bed <NUM> may be the same only except for a difference in a vertical position thereof. The water supplied to the bed water collector <NUM> may supply moisture to the cultivator <NUM> mounted on the bed <NUM>.

In one example, (a) in <FIG> is a perspective view showing one embodiment of a cultivator in the plant cultivation apparatus according to an embodiment of the present disclosure. (b) in <FIG> is an exploded view showing an embodiment of the cultivator in the plant cultivation apparatus according to an embodiment of the present disclosure.

As shown in <FIG>, the cultivator <NUM> may include a cultivation vessel <NUM> seated on the bed <NUM> and constructed to have an open top, and a cover <NUM> for shielding the open top of the cultivation vessel <NUM>.

The cultivation vessel <NUM> may be constructed to have the open top, and may be seated on the bed <NUM>. Accordingly, the user may select the cultivator <NUM> corresponding to a type of the plant to be cultivated and may seat the selected cultivator <NUM> at a desired position on the bed <NUM> to start cultivation of the plant.

Further, the cultivation vessel <NUM> may include a bottom surface <NUM> of the cultivation vessel and may have a cultivation medium receiving space S2 defined therein and may be coupled to the cover <NUM>.

Further, the cultivation vessel <NUM> may have a first communication hole <NUM> defined therein through which water in the cultivation medium receiving space S2 is discharged to the communication channel <NUM>, as will be described later. The cultivation medium receiving space S2 may receive water from the water supply <NUM> through the first communication hole <NUM>. The water in the cultivation medium receiving space S2 may be collected back into the water supply <NUM>. Further, the first communication hole <NUM> may be defined in the bottom surface <NUM> of the cultivation vessel <NUM> and communicate with the communication channel <NUM> disposed in the bed.

The cultivator <NUM> may include a cultivation filter <NUM> disposed on the bottom surface <NUM> of the cultivation vessel <NUM> for removing foreign substances from the water discharged or inflowing through the first communication hole <NUM>. The foreign material removed using the cultivation filter <NUM> may be a portion of the cultivation medium <NUM> produced in the plant growth process, or may be a portion of the root of the plant.

Further, the foreign material may be a portion of a stem or a leaf of a plant that is produced due to an upper water supply structure to be described later. The cultivation filter <NUM> may be configured to shield the first communication hole <NUM>, and to prevent inflow of foreign substances as produced in the cultivation medium receiving space into the water supply <NUM>.

In one example, the cultivation vessel <NUM> may have the cultivation medium receiving space S2 defined therein for receiving therein the cultivation medium <NUM> in which at least a portion of the plant is received. The cultivation medium <NUM> may be received in the cultivation medium receiving space S2 defined in the cultivation vessel <NUM>. The cultivation medium <NUM> may extend vertically from the bottom surface <NUM> of the vessel toward the cover <NUM> by a predetermined vertical dimension H3.

Nutrients necessary for the plant growth may be contained in the cultivation medium <NUM>. When only water is supplied to the cultivation medium <NUM> without supply of additional components thereto, the plant growth may proceed at an adequate rate.

Further, the cultivation medium <NUM> may include a cultivation medium body <NUM> that defines the outer appearance of the cultivation medium <NUM> and a cultivation medium hole <NUM> that is defined at a top portion of the cultivation medium body. The cultivation medium <NUM> contains the seeds of the plant. The cultivation medium may be made of various materials capable of absorbing the water stored in the cultivation medium receiving space S2 and supplying the water to seeds or roots inside the cultivation medium <NUM>.

In one example, the cover <NUM> may cover the cultivation medium receiving space S2 of the cultivation vessel <NUM>. A top of the cultivation vessel <NUM> is open. Thus, the cover <NUM> may be disposed at a top of the cultivation vessel and may be coupled to the cultivation vessel <NUM>.

In one example, the cultivation medium receiving space S2 may store therein water supplied to the cultivation medium <NUM>. When the water is exposed to air out of the cultivator and to light from an artificial light source (not shown), reproduction of microorganisms in the water may become active, thereby adversely affecting the growth of the plant.

In order to prevent this situation, the cover <NUM> may cover the cultivation medium receiving space S2 of the cultivation vessel <NUM>, so that the cultivation medium receiving space is prevented from being exposed to an environment out of the cultivator <NUM>. Due to the cover <NUM>, the water stored inside the cultivation medium receiving space S2 may be prevented from being exposed to light irradiated from the artificial light source (not shown) disposed above the top of the cultivator <NUM>. Contact of the water with the air outside the cultivator <NUM> may be prevented.

Further, due to the cover <NUM>, the roots of the plant grown in the cultivation medium <NUM> may be prevented from being exposed to the light source (not shown), so that the growth of the plant may be improved.

The cover <NUM> may be coupled to the cultivation vessel <NUM> using a bolt-nut structure. However, the disclosure is not limited thereto. Hereinafter, as shown in the drawings, an example in which the cover <NUM> is coupled to the cultivation vessel <NUM> in a press-fitting manner is described.

In one example, the plant cultivation apparatus <NUM> according to one embodiment of the present disclosure includes a nutrient feeder <NUM> located in the cultivation medium receiving space S2. The nutrient for the plant is received in the nutrient feeder <NUM>.

The nutrient feeder <NUM> may be disposed to be spaced apart from the bottom surface <NUM> of the cultivation vessel <NUM>. When the nutrient feeder <NUM> is brought into contact with water stored in the cultivation medium receiving space S2, the nutrient therein may be mixed with the water and then the mixture may be supplied to the cultivation medium.

In one example, the cover <NUM> may include a cultivation medium receiving portion <NUM> which is formed at a position corresponding to that of the cultivation medium <NUM> and into which an upper end of the cultivation medium is inserted. Due to the cultivation medium receiving portion <NUM>, the cultivation medium <NUM> may be fixedly received inside the cultivation vessel <NUM> when the cover <NUM> is coupled to the cultivation vessel.

The cover <NUM> may have a predetermined vertical dimension H2 and may extend from a bottom to a top thereof. The cultivation medium receiving portion <NUM> may have a vertical dimension equal to the vertical dimension H2 of the cover <NUM> such that the upper end of the cultivation medium <NUM> may be received therein.

The number of the cultivation medium receiving portions <NUM> may correspond to the number of the cultivation mediums <NUM>. In order to fix the position of the cultivation medium <NUM>, the number of the cultivation medium receiving portions <NUM> may be greater than or equal to the number of the cultivation medium <NUM>.

As shown in (b) in <FIG>, the cultivation medium receiving portion <NUM> may be defined in a top face of the cover. The cultivation medium receiving portion <NUM> may include a plurality of the cultivation medium receiving portions. The present disclosure is not necessarily limited thereto. A distance between adjacent ones of the plurality of cultivation medium receiving portions <NUM> may be appropriately designed according to the type of plant to be cultivated.

The cultivation medium receiving portion <NUM> may have a cover through-hole <NUM> defined at a position thereof corresponding to a position of the cultivation medium <NUM> so as to expose at least a portion of a top face of the cultivation medium <NUM>. The cover through-hole <NUM> may extend through the top face of the cover <NUM>.

A seed of the plant received in the cultivation medium hole <NUM> germinates. A stem of the plant may extend through the cover through-hole <NUM> and may grow toward a space above the top of the cover <NUM>. Therefore, for smooth growth of the plant, a diameter of the cover through-hole <NUM> may be defined to be larger than a diameter of the cultivation medium hole <NUM>.

That is, in a top view of the cultivator <NUM>, the cover through-hole <NUM> may be defined to expand along a radial direction of the cultivation medium hole <NUM>. The diameter of the cover through-hole <NUM> may be appropriately designed in consideration of the size of the plant being cultivated.

Further, a center of the cover through-hole <NUM> may be positioned to correspond to a center of the cultivation medium hole <NUM>. Thus, when the plant germinates and grows, and thus extends to be exposed to a space out of the cultivation medium <NUM>, the plant may be recognized by the user due to the cover through-hole <NUM>.

In one example, the cultivator <NUM> may further include an indicator <NUM> disposed above the top face of the cover <NUM> to minimize exposure of the cultivation medium <NUM>. A seed name of the plant may be written on the indicator. The seed name of the plant may be marked on the indicator <NUM> so that the type of the plant grown in the cultivation space may be easily recognized by the user.

The indicator <NUM> may be constructed to cover the top face of the cover <NUM>. As shown in the figure, the indicator <NUM> may include a plurality of indicators and may be disposed above the top face of the cover <NUM>. The indicator <NUM> may be coupled to a remaining area of the cover <NUM> except for a cover coupler <NUM>.

Thus, in the top view of the cultivator <NUM>, a top face <NUM> of the indicator <NUM> may be exposed to the outside, and a top face of the cover except for the cover coupler <NUM> may not be exposed to the outside.

The indicator <NUM> may have an indicator hole <NUM> defined therein at a position corresponding to that of the cover through-hole <NUM> and may have a diameter smaller than the diameter of the cover through-hole <NUM>, so that exposure of the cultivation medium <NUM> to the outside may be prevented. The plant may grow and extend through the indication hole <NUM> and toward a space above the top of the cultivator <NUM>.

<FIG> is a side view showing an embodiment of a cultivator including the nutrient feeder <NUM> in the plant cultivation apparatus <NUM> according to an embodiment of the present disclosure.

The nutrient feeder <NUM> may be disposed to be spaced apart from the cultivation medium receiving portion <NUM>, and may be coupled to the bottom surface of the cover <NUM>.

A bottom portion <NUM> of the nutrient feeder <NUM> may be spaced apart from the bottom surface <NUM> of the cultivation vessel <NUM> by a predefined spacing H6. The nutrient feeder <NUM> may have a nutrient storage space S3 defined therein, so that nutrient N required for the plant growth may be stored in the nutrient storage space S3.

Further, the nutrient feeder <NUM> may have a nutrient feeding hole <NUM> defined therein communicating with the cultivation medium receiving space S2. The nutrient feeder <NUM> may be constructed such that when the water stored in the cultivation medium receiving space S2 flows into the nutrient feeder <NUM>, the water together with the nutrient N may be discharged through the nutrient feeding hole <NUM>.

One face of the nutrient feeder <NUM> facing toward the cultivation medium receiving space S2 may be made of a mesh material, so that the nutrient N may be dissolved in the water which may, in turn, be supplied to the cultivation medium receiving space S2.

The nutrient N may be embodied as water-soluble solid dissolved in the water. The disclosure is not necessarily limited thereto. As long as the nutrient N is mixed with the water flowing into the nutrient storage space S3 and the mixture is discharged to the cultivation medium receiving space S2, a type of the nutrient N may not be particularly limited.

Further, the nutrient feeder <NUM> may include a side face <NUM> extending from the cover <NUM> toward the bottom surface <NUM> of the cultivation vessel <NUM>, and the bottom portion <NUM> extending from the side face <NUM> in a horizontal direction. The nutrient feeding hole <NUM> may be defined in the bottom portion <NUM>.

The side face <NUM> and the bottom portion <NUM> together with the bottom surface of the cover <NUM> may define the nutrient storage space S3. A size of each of the side face <NUM> and the bottom portion <NUM> may be appropriately set according to a size of the plant, and a size of each of the cultivation medium, the cultivation medium vessel, and the cover <NUM>.

The nutrient feeding hole <NUM> may be defined in the side face <NUM>. The nutrient feeder <NUM> may include a plurality of feeders. The nutrient feeding hole <NUM> may include a plurality of holes.

The bottom portion <NUM> of the nutrient feeder <NUM> may be spaced apart from the bottom surface <NUM> of the cultivation vessel <NUM> by the predefined spacing H6. When the nutrient feeding hole <NUM> is defined in the bottom portion <NUM>, the nutrient feeding hole <NUM> may be spaced from the bottom surface <NUM> of the cultivation vessel <NUM> by the predefined spacing H6.

When the nutrient N is embodied as a solid, a size of the solid may be larger than a size of the nutrient feeding hole <NUM>. Thus, when water does not flow into the nutrient feeder <NUM>, the nutrient N may be prevented from flowing through the nutrient feeding hole <NUM>.

A distance between both opposing side faces <NUM> of the nutrient feeder <NUM> may be defined as a diameter thereof. The distance may be defined to be smaller than a distance between adjacent one of a plurality of cultivation mediums <NUM>.

In one example, the first water supply channel5 may include a first lower supply channel52 and a first upper supply channel51. The first water supply channel5 may include the communication channel <NUM> which is disposed in the bed <NUM> and communicates with the first communication hole <NUM>, and supplies water from the bed water collector <NUM> to the first communication hole <NUM> or collects the water from the bed water collector <NUM>.

Further, the water supplied to the cultivator <NUM> through the communication channel <NUM> may be continuously supplied to the cultivator <NUM>. In detail, the communication channel <NUM> may communicate with the bed water collector <NUM>. The communication channel <NUM> may communicate with the storage (not shown) included in the water supply <NUM> which will be described later, so that the water discharged from the cultivator <NUM> may be discharged to the storage (not shown) through the communication channel <NUM>.

Further, a predetermined vertical level H3 of the water F supplied from the first water supply channel5 to the cultivation medium receiving space S2 through the communication channel <NUM> may be defined.

When the water is continuously supplied from the first water supply channel5 to the cultivation medium receiving space S2, the vertical level H3 of the water F may be increased. When the vertical level of the water is higher than the vertical level H6 of the nutrient feeding hole <NUM>, the water inflows into the nutrient storage space S3 and thus the nutrient N may be dissolved in the water. The dissolved nutrient N may be fed back to the cultivation medium <NUM> through the nutrient feeding hole <NUM>.

Thus, due to the above structure, the plant cultivation apparatus <NUM> according to an embodiment of the present disclosure adjusts an inflow amount of water supplied into the cultivation medium receiving space S2 when additional nutrient supply is required such that the nutrient N from the nutrient feeder <NUM> may be supplied to the plant.

In one example, <FIG> is a perspective view showing another embodiment of a cultivator in the plant cultivation apparatus according to one embodiment of the present disclosure. Hereinafter, descriptions duplicate with those of the above-described structure will be omitted.

In the plant cultivation apparatus <NUM> according to an embodiment of the present disclosure, the cultivator <NUM> may be seated on the bed <NUM> and may include the cultivation vessel <NUM> having an open top, and a cover <NUM> for shielding the open top of the cultivation vessel <NUM>.

Further, the cultivator may further include a cover channel <NUM> disposed in a top face of the cultivator <NUM> for receiving water to be supplied to the plant. The water supply <NUM> may include a second water supply channel2.

The second water supply channel2 may be constructed such that at least a portion of the second water supply channel2 is positioned above the cover channel <NUM> such that the water to is fed to the cover channel <NUM> therethrough.

Further, the cover channel <NUM> may be disposed in the top face of the cover. The cover channel <NUM> may be constructed to communicate with the inside of the cultivator <NUM> so that the water supplied from the second water supply channel2 is guided to the cultivation medium therethrough.

The water supply <NUM> may include a supply channel that supplies water to the cultivator <NUM>, and storage (not shown) that supplies water to the cultivator <NUM> and collects the water therefrom and stores the collected water therein.

As shown in <FIG>, the water supply <NUM> may be configured to supply water to the bed water collector <NUM> of the bed <NUM> through the first water supply channel5.

Further, as shown in <FIG>, the water supply <NUM> may be configured to supply water to the cover channel <NUM> through the second water supply channel2.

Specifically, the second water supply channel2 may include a second upper supply channel21 for supplying water to the cover channel <NUM> of the upper bed <NUM> among the plurality of beds <NUM>, and a second lower supply channel22 that supplies water to the cover channel <NUM> of the lower bed <NUM>.

Each of the second upper supply channel21 and the second lower supply channel22 may be disposed independently, and may extend to face toward each of the cover channels <NUM>, so that water necessary for plant growth may be supplied thereto.

The second water supply channel2 may be connected to the storage (not shown) and may extend upward. The water flows from the storage (not shown) into the second water supply channel2 along which the water flows upward.

Further, the second upper supply channel21 and the second lower supply channel22 may have a second upper supply branch channel <NUM> and a second lower supply branch channel <NUM> facing toward upper and lower cover channels <NUM> and supplying water to the upper and lower cover channels <NUM>, respectively.

<FIG> is an exploded view showing another embodiment of a cultivator in the plant cultivation apparatus according to one embodiment of the present disclosure. <FIG> is a perspective view showing another embodiment of a cultivator in the plant cultivation apparatus according to one embodiment of the present disclosure. Hereinafter, descriptions duplicate with those of the above-described structure will be omitted.

The cover channel <NUM> may be constructed to overlap with at least a portion of the cultivation medium receiving portion <NUM>. In other words, the cover channel <NUM> may be constructed such that one face of the cultivation medium receiving portion <NUM> is exposed to the inside of the cover channel <NUM>.

Further, the cultivation medium receiving portion <NUM> may have a second inflow hole <NUM> for providing water from the cover channel <NUM> to the cultivation medium <NUM>. The second inflow hole <NUM> may be defined to be exposed to the inside of the cover channel <NUM>. The water supplied from the supply channel to the cover channel <NUM> is received in the cover channel <NUM>, and flows into the second inflow hole <NUM>, and then is supplied to the cultivation medium <NUM>.

As shown in <FIG>, the cover channel <NUM> may include a first cover channel <NUM> extending from one side to the opposite side of the cover and a second cover channel <NUM> branching from the first cover channel <NUM>. A direction in which the first cover channel <NUM> extends may be a direction in which the cultivator <NUM> extends toward the door <NUM> as described above.

Further, a direction in which the second cover channel <NUM> branches from the first cover channel <NUM> and extends may be inclined relative to a direction in which the first cover channel <NUM> extends. As shown in <FIG>, the direction in which the second cover channel <NUM> branches from the first cover channel <NUM> and extends may be perpendicular to the direction in which the first cover channel <NUM> extends.

Further, the cover channel <NUM> may be defined by depressing a portion of the top face of the cover <NUM>. The cultivation medium receiving portion <NUM> may protrude upward from a bottom surface <NUM> of the cover channel <NUM> and may be positioned inside the cover channel <NUM>.

As described above, the cultivation medium <NUM> may include a plurality of mediums. The cultivation medium receiving portion <NUM> may include a plurality of cultivation medium receiving portions. Thus, the cover channel <NUM> may extend so as to connect a plurality of points corresponding to positions of the plurality of cultivation medium <NUM> to each other.

Further, the plurality of cultivation medium receiving portions <NUM> may be constructed to be positioned inside the first cover channel <NUM> and the second cover channel <NUM>. Accordingly, the second inflow hole <NUM> through which the water stored in the cover channel <NUM> flows into the inside of the cultivation medium receiving portion <NUM> may include a plurality of second inflow holes arranged along a circumference of the cultivation medium receiving portion <NUM>. Thus, the water in the cover channel <NUM> may be more smoothly supplied to the cultivation medium <NUM>.

The second inflow hole <NUM> may be in contact with the bottom surface <NUM> of the cover channel <NUM> so that the water received in the cover channel <NUM> may flow into the second inflow hole.

The cultivation medium <NUM> may be in contact with the inner face of the cultivation medium receiving portion <NUM>. The upper end of the cultivation medium <NUM> may be inserted into the cultivation medium receiving portion. The second inflow hole <NUM> may be constructed to extend from the inner face of the cultivation medium receiving portion <NUM> toward the cover channel <NUM> to guide the water received in the cover channel <NUM> to the cultivation medium <NUM>.

In one example, a longitudinal direction I1 of the cultivation medium receiving portion <NUM> along an extending direction of the first cover channel <NUM> may be equal to a transverse length <NUM> of the cultivation medium receiving portion <NUM> perpendicular to the extending direction of the first cover channel <NUM>. The longitudinal and transverse lengths I1 and <NUM> of the cultivation medium receiving portion <NUM> may be sized based on a shape of the cultivation medium <NUM>.

A width I3 of the cover channel <NUM> perpendicular to the extending direction of the first cover channel <NUM> may be defined to be larger than each of the transverse lengths I1 and I2 of the cultivation medium receiving portion <NUM>. Thus, the flow of water along the cover channel <NUM> may be achieved smoothly.

Further, the cultivation medium receiving portion <NUM> may be spaced apart from a sidewall <NUM> of the cover channel <NUM> by a predefined spacing <NUM>. The predefined spacing I5 between the sidewalls <NUM> of the cover channel <NUM> and the cultivation medium receiving portion <NUM> may be sized so that the flow of water along the cover channel <NUM> is not too fast.

The predefined spacing I5 may be appropriately designed based on a vertical dimension of the cover channel <NUM> in the top face of the cover <NUM>, a size of the cultivation medium receiving portion <NUM>, and an amount of water supplied to the cover channel <NUM>.

Further, the sidewall <NUM> of the cover channel <NUM> may be formed such that a portion thereof facing toward the cultivation medium receiving portion <NUM> is recessed in a direction away from the cultivation medium receiving portion <NUM>.

In other words, the portion of the sidewall <NUM> of the cover channel <NUM> facing toward the cultivation medium receiving portion <NUM> closest thereto may be recessed so as to be spaced from the cultivation medium receiving portion <NUM> by the predefined spacing I4, thereby defining a predetermined space between the cultivation medium receiving portion <NUM> and the sidewall.

Thus, the water moving around the cultivation medium receiving portion <NUM> may be received in a larger amount in a space between the cultivation medium receiving portion <NUM> and the sidewall <NUM> of the cover channel <NUM>.

Thus, a time duration for which the water received in the space between the cultivation medium receiving portion <NUM> and the sidewall <NUM> of the cover channel <NUM> is in contact with the cultivation medium receiving portion <NUM> may be increased. Thus, a time duration for which the water flows into the second inflow hole <NUM> of the cultivation medium receiving portion <NUM> may be increased.

In one example, the cover channel <NUM> may have a first inflow hole <NUM> which communicates with the nutrient storage space S3 inside the nutrient feeder <NUM>. The water may be supplied to the nutrient feeder <NUM> through the first inflow hole <NUM>.

The water supplied from the cover channel <NUM> through the first inflow hole <NUM> may flow into the nutrient storage space S3. The nutrient N may be dissolved in and missed with the water. The mixture solution may flow through the nutrient feeding hole <NUM>.

Further, as a vertical dimension from the bottom surface <NUM> of the cover channel <NUM> to the first inflow hole <NUM> is smaller, the inflow of water from the cover channel <NUM> to the first inflow hole <NUM> may be achieved more efficiently. Accordingly, the first inflow hole <NUM> may be in contact with the bottom surface <NUM> of the cover channel <NUM> so that the water received in the cover channel <NUM> may flow into the first inflow hole.

In other words, a portion of a diameter of one end of the first inflow hole <NUM> exposed toward the inside of the cover channel <NUM> may be in contact with the bottom surface <NUM> of the cover channel <NUM>.

Thus, after the supply of water from the second water supply channel2 is finished, the water supplied to the cover channel <NUM> does not remain on the bottom surface <NUM> of the cover channel <NUM> but an entire amount thereof flows into the second inflow hole <NUM>. Then, the water together with the nutrient N may be supplied to the cultivation medium receiving space S2.

In one example, the cover channel <NUM> may include protrusions <NUM> and <NUM> protruding upward from the bottom surface <NUM> of the cover channel <NUM>. The protrusions <NUM> and <NUM> may include a first protrusion <NUM> positioned on one side of the cover <NUM> and positioned closer to the water supply <NUM> than the cultivation medium receiving portion <NUM> is.

Further, the protrusions <NUM> and <NUM> may further include a second protrusion <NUM> located on the opposite side of the cover. The first protrusion <NUM> and the second protrusion <NUM> may be respectively disposed at one side and the opposite side in the extending direction of the first cover channel.

Because the first protrusion <NUM> and the second protrusion <NUM> are disposed at one side and the opposite side, respectively, a flow rate of water moving inside the cover channel <NUM> may be kept constant.

The cover channel <NUM> may include a third inflow hole <NUM> defined in a top face of each of the protrusions <NUM> and <NUM> and communicating with the inside of the cultivation vessel. In other words, the third inflow hole <NUM> may be constructed to communicate with the cultivation medium receiving space S2. Water from the cover channel <NUM> may flow into the cultivation medium <NUM> through the third inflow hole <NUM>.

Further, when the amount of water supplied from the supply channel to the cover channel <NUM> is too large, the water supplied to the cover channel <NUM> through the third inflow hole <NUM> may be guided to the cultivation medium receiving space S2.

Further, depending on the type of the plant cultivated in the plant cultivation apparatus <NUM>, the amount of the water supplied to the cultivator <NUM> may be greater than an amount in which the cover channel <NUM> may receive the water.

The water may be supplied to the cultivation medium through the first inflow hole <NUM> communicating with the nutrient feeder <NUM>, the second inflow hole <NUM> defined in the cultivation medium receiving portion, and the third inflow hole <NUM> defined in each of the protrusions <NUM> and <NUM>.

In one example, <FIG> is a top face view and a side view showing a cultivator in the plant cultivation apparatus according to one embodiment of the present disclosure. (a) in <FIG> shows a top view of the cultivator <NUM>. (b) in <FIG> shows a side view of the cultivator <NUM>. Hereinafter, descriptions duplicate with those of the above-described structures will be omitted.

In the plant cultivation apparatus <NUM> according to an embodiment of the present disclosure, the nutrient feeder <NUM> may be constructed to protrude upward from the bottom surface <NUM> of the cover channel <NUM> and to be spaced apart from the cultivation medium receiving portion <NUM>.

Specifically, a second cover channel <NUM> of the cover channel <NUM> may define a channel along the circumference of the nutrient feeder <NUM>. A plurality of first inflow holes <NUM> may be arranged along the circumference of the nutrient feeder <NUM>.

That is, the first inflow hole <NUM> may extend through the side face <NUM> of the nutrient feeder <NUM>, so that the cover channel <NUM> and the nutrient storage space S3 communicate with each other via the first inflow hole <NUM>.

The first inflow holes <NUM> may include a plurality of holes. Thus, the water supplied to the cover channel <NUM> may efficiently flow into the nutrient storage space S3. Thus, the nutrient N may be efficiently supplied to the cultivation medium <NUM> through the nutrient feeding hole <NUM>.

A size of the nutrient feeder <NUM> may be defined to correspond to a size of the cultivation medium receiving portion <NUM>. The nutrient feeder <NUM> may be constructed to be spaced apart from the cultivation medium receiving portion <NUM>.

In one example, the first inflow hole <NUM> may be defined to contact the bottom surface <NUM> of the cover channel <NUM>. In some cases, the second inflow hole <NUM> may be disposed to be spaced apart from the bottom surface <NUM> of the cover channel <NUM>, so that a predetermined vertical spacing may be defined between the bottom surface <NUM> of the cover channel and the second inflow hole <NUM>.

This is because the nutrient N may be efficiently supplied to the cultivation medium <NUM> when the water supplied to the cover channel <NUM> flows into the first inflow hole <NUM> rather than when the water supplied to the cover channel <NUM> flows into the second inflow hole <NUM>.

In one example, the supply channel may have discharge holes <NUM> and <NUM> through which water is discharged to the cover channel <NUM>. The cover <NUM> may include a water collector <NUM> which may be located below the discharge holes <NUM> and <NUM>. Thus, the water discharged from the discharge holes <NUM> and <NUM> may be supplied to the water collector <NUM>. The cover channel <NUM> may be constructed to be connected to the water collector <NUM> and to receive water therefrom.

Further, the water collector <NUM> may be disposed at each of one side and the opposite side in the direction in which the cover channel <NUM> extends. The first protrusion <NUM> may include a pair of protrusions. The water collector <NUM> may be positioned between the pair of the first protrusions <NUM> and may collect the water supplied from the discharge holes <NUM> and <NUM> and guide the collected water to the cover channel <NUM>.

Further, the water collector <NUM> may have a predetermined vertical dimension H4 based on the bottom surface <NUM> of the cover channel <NUM>. The water collector <NUM> may be inclined such that a vertical level thereof is lowered as the collector <NUM> extends toward the cover channel <NUM>. One end thereof connected to the cover channel <NUM> together with the bottom surface <NUM> of the cover channel <NUM> may define a continuous face.

When the vertical dimension of the discharge holes <NUM> and <NUM> from the bottom surface <NUM> of the cover channel <NUM> is excessively larger, water falling to the water collector <NUM> may flow out of the cover channel <NUM>.

However, due to the structure in which the water collector <NUM> has the inclination such that a vertical level thereof is lowered as the collector <NUM> extends toward the cover channel <NUM>, the water collector <NUM> may minimize water leakage to the outside of the cover channel <NUM> while stably guiding the water toward the cover channel <NUM>.

In one example, <FIG> is a diagram showing a water supply process of several embodiments in the plant cultivation apparatus according to one embodiment of the present disclosure. Hereinafter, descriptions duplicate with those of the above-described structures will be omitted.

(a) and (b) in <FIG> show the process of supplying water to the nutrient storage space S3 of the nutrient feeder <NUM> through the second water supply channel2. The structures of the cover <NUM> and the cover channel <NUM> are the same as the structures shown in <FIG>. Thus, the structures of the cover <NUM> and the cover channel <NUM> are omitted from <FIG>. Hereinafter, descriptions will be made while the structures of the cover <NUM> and the cover channel <NUM> are omitted.

Hereinafter, a vertical level of a component may be defined as a vertical dimension from the bottom surface <NUM> of the cultivation vessel <NUM>.

The plant cultivation apparatus <NUM> according to an embodiment of the present disclosure may further include a controller <NUM> for controlling the water supply <NUM>. The controller <NUM> may be configured to control a supply pump (not shown) that controls the supply of water in the water supply <NUM>, and a branching valve (not shown) that controls the opening and closing of the first water supply channel5 and the second water supply channel2.

In one example, as shown in (a) in <FIG>, in a state where additional nutrient N is not required, water is not supplied to the nutrient feeder <NUM>, and water is supplied from the communication channel <NUM> to the cultivation medium receiving space S2 through the first water supply channel5.

In this case, the controller <NUM> may block the second water supply channel2 and may allow the water to be supplied to the cultivation medium receiving space S2 through the first water supply channel5. In other words, the controller <NUM> may adjust the branching valve (not shown) to supply water to the cultivator <NUM> selectively through one of the first water supply channel5 and the second water supply channel2.

When water is supplied to the cultivation medium receiving space S2, a vertical level H5 of the water-surface of the cultivation medium receiving space S2 may be lower than a vertical level H6 of the nutrient feeding hole <NUM>. Accordingly, it may be prevented that the water in the cultivation medium receiving space S2 flows into the nutrient feeder <NUM>, and thus the nutrient N is dissolved in water and thus the mixed solution flows through the nutrient feeding hole <NUM>.

As shown in (b) in <FIG>, when additional nutrient is needed in the cultivation medium <NUM>, the controller <NUM> may control the water supply <NUM> to block the first water supply channel5 and allow the water to be supplied into the cover channel <NUM> through the second water supply channel2.

In this case, water flows into the nutrient storage space S3 in the nutrient feeder <NUM> and thus the nutrient N in the nutrient feeder <NUM> is dissolved in and mixed with water and thus the mixed solution flows into the cultivation medium receiving space S2.

In one example, as shown in (c) in <FIG>, in a state where additional nutrient N is not required, water is not supplied to the nutrient feeder <NUM>, and water from the communication channel <NUM> is supplied to the cultivation medium receiving space S2 through the first water supply channel5. The supply schemes of the water to the cultivation medium receiving space in (a) and (b) in <FIG> may be the same as each other.

Further, in (c) in <FIG>, when water is supplied to the cultivation medium receiving space S2, the vertical level H5 of the water-surface of the cultivation medium receiving space S2 may be lower than the vertical level H6 of the nutrient feeding hole <NUM>. Accordingly, it may be prevented that the water in the cultivation medium receiving space S2 flows into the nutrient feeder <NUM>, and thus the nutrient N is dissolved in water and thus the mixed solution flows through the nutrient feeding hole <NUM>.

In one example, as shown in (d) in <FIG>, when it is determined that the supply of additional nutrient N is necessary, the water supply may be controlled so that the water is supplied to the first water supply channel5 such that a vertical level H7 of the water-surface in the cultivation medium receiving space S2 is higher than the vertical level H6 of the nutrient feeding hole.

As will be described later, in (a) and (c) in <FIG>, the controller <NUM> may control the water supply <NUM> to perform a general mode S100. Further, in (b) in <FIG>, the controller <NUM> may control the water supply <NUM> to perform an upper water supply mode S340. Further, in (d) in <FIG>, the controller <NUM> controls the water supply <NUM> to perform an additional water supply mode S330.

The upper water supply mode S340 is the same as the additional water supply mode S330 in that in both modes, the water is supplied from the water supply <NUM> to the nutrient feeder <NUM>. The additional water supply mode S330 may be different from the upper water supply mode S340 in that the vertical level of the water in the cultivation medium receiving space S2 in the additional water supply mode S330 is higher than that in the upper water supply mode S340.

That is, the additional water supply mode S330 may be performed when it is necessary to additionally supply the amount of water supplied to the cultivation medium <NUM> based on the type of the plant.

<FIG> is a view showing a control mode performed by the controller in the plant cultivation apparatus according to an embodiment of the present disclosure. Hereinafter, descriptions duplicate with those of the above-described structures will be omitted.

The controller <NUM> may be configured to control the water supply <NUM> to perform the general mode S100 as described above in a general mode execution operation S100 to supply the water to the cultivation medium <NUM>. After the general mode execution operation S100, the controller <NUM> may perform a nutrient supply determination operation S200 to determine whether it is necessary to supply additional nutrient N to the cultivation medium <NUM>.

A result of the nutrient supply determination operation S200 may be determined based on the user's input or a growth stage of the plant stored in the memory.

When it is determined that there is no need for additional nutrient supply in the nutrient supply determination operation S200, the controller <NUM> may perform the general mode execution operation S100.

Conversely, when it is determined that additional nutrient supply is necessary in the nutrient supply determination operation S200, the controller <NUM> may control the water supply <NUM> to perform a nutrient supply operation S300 to supply water to the nutrient feeder <NUM>.

The controller <NUM> may perform a nutrient liquid level measurement operation S310 for measuring the vertical level of the water-surface using a sensor (not shown) for measuring a vertical level of a water surface in the cultivation medium receiving space S2.

After the nutrient liquid level measurement operation S310, it may be determined in the nutrient liquid additional water supply determination operation S320 that it is necessary to increase the vertical level H7 of the water-surface to be higher than the vertical level H7 of the nutrient feeding hole. In this case, the controller may perform the additional water supply mode S330.

Conversely, after the nutrient liquid level measurement operation S310, it may be determined in the nutrient liquid additional water supply determination operation S320 that it is not necessary to increase the vertical level H7 of the water-surface to be higher than the vertical level H7 of the nutrient feeding hole. In this case, the controller <NUM> may perform the upper water supply mode S340.

In this way, the controller <NUM> may control the water supply <NUM> to supply the nutrient based on the growth stage of the plant. Thus, the user's convenience and the efficiency of the plant cultivation may be increased.

Claim 1:
A plant cultivation apparatus comprising:
a cabinet (<NUM>);
a bed (<NUM>) disposed in the cabinet;
a cultivator (<NUM>) seated on the bed, the cultivator designed to receive therein a cultivation medium in which at least a portion of a plant is received; and
a water supply (<NUM>) disposed at the cabinet and configured to supply water to the cultivator,
wherein the cultivator includes:
a cultivation vessel (<NUM>) seated on the bed and having defined therein a cultivation medium receiving space (S2) for receiving the cultivation
medium; the cultivation vessel (<NUM>) having an open top so that the cultivation medium receiving space is exposed outwardly through the open top;
a nutrient feeder (<NUM>) located in the cultivation medium receiving space, the nutrient feeder designed to hold a nutrient for the plant; and
a cover (<NUM>) disposed on the open top of the cultivation vessel to close the cultivation medium receiving space;
wherein the cultivation vessel is configured such that water supplied from the water supply flows into the cultivation medium receiving space and is fed to the cultivation medium therein,
wherein the nutrient feeder is spaced apart from a bottom surface (<NUM>) of the cultivation vessel,
wherein the nutrient of the nutrient feeder is mixed with the water in contact with the nutrient feeder inside the cultivation medium receiving space and supplied to the cultivation medium with the water, characterised in that
the cultivator includes a cover channel (<NUM>) defined in a top face of the cover and configured to receive water supplied from the water supply,
wherein the cover channel has a first hole communicating with the inside of the nutrient feeder, wherein water is supplied to the nutrient feeder through the first inflow hole.