A plant growing vessel includes an impervious outer vessel, a cover, a first permeable membrane, a nutrient chamber, and a pocket. The impervious outer vessel includes an inert substrate in a root zone. The cover is positioned over the impervious outer vessel. The first permeable membrane is in contact with the inert substrate. The nutrient chamber includes solid nutrients. The nutrient chamber is between the cover and the first permeable membrane or between the first permeable membrane and a bottom of the impervious outer vessel, and the solid nutrients are in contact with the first permeable membrane. The pocket is configured to allow seeds, seedlings, or shoots of plants access to the inert substrate through an aperture in the cover.

A green roof planter module includes a planter including a bottom wall and a plurality of side walls that cooperate with one another to define an interior space configured to receive an aggregate and plant matter therein, the bottom wall including at least one aperture extending therethrough, a basin including a bottom wall and a plurality of side walls, wherein the bottom wall of the basin and the side walls of the basin cooperate to define a fluid retention space, wherein the planter is supported above the basin, and a fluid wicking member providing fluid communication from the fluid retention space of the basin to the at least one aperture of the bottom wall of the planter, such that the fluid wicking member is configured to transfer fluid from the fluid retention space of the basin to the aggregate and plant matter located with the interior space of the planter.

A plant pallet has a plurality of wells arranged in rows and columns to receive leafy tree seedlings. The wells each have a well bottom with at least one drainage opening. The well bottom of each well merges laterally into a peripheral side wall. A top side of the plant pallet is formed by side walls of adjacent wells merging into one another. To prevent lateral rooting being impaired or adversely affected by the side wall, protrusions which extend further upwards are arranged on the top side such that they partially continue the side walls upwards.

A semi-rigid plant container is formed of silicone to provide various semi-rigid, but resilient characteristics. The semi-rigid plant container includes abase having at least one drainage opening and a sidewall. The sidewall rises from the base and presents a top edge, an inner surface, and an outer surface. The inner surface of the sidewall and the base are configured to receive a plant growing media therein. The sidewall is formed substantially of silicone.

An aquatic weed planting plate for an aquarium is provided. The aquatic weed planting plate for aquarium includes a plate body and at least four feet. A plurality of planting holes is formed in the plate body at intervals. A plurality of dirt collecting holes is formed around each planting hole. The plate body is provided with fixing devices for fixing aquatic weeds, and each fixing device corresponds to one planting hole. The fixing device includes a fixing sleeve, two clamping members and a luminous ring. The plate body is provided with nets for collecting dirt, each net corresponds to one dirt collecting hole, the lower portion of each net is provided with a connecting tube; a plurality of conveying pipes is also arranged below the plate body, each conveying pipe is communicated with the plurality of connecting tubes, each connecting tube is communicated with the corresponding conveying pipe.

A seedling raising device includes: a cell plug for seedling raising that is formed as a single pot body; and a supporting device configured to detachably arrange and support a plurality of cell plugs, wherein the supporting device is capable of supporting the cell plug in either one of a first supporting position where the cell plug is slidably supported in a horizontal direction and a second supporting position where the cell plug is detachably supported in a top position.

The invention relates to a method for the substrate-free rooting of a plurality of unrooted cuttings, comprising the steps: providing a carrier strip having a plurality of cavities which are open at the top for receiving in each case an unrooted cutting in each cavity, wherein each cavity is provided with openings at least in a region associated with a cutting base, inserting an unrooted cutting into each cavity, applying a water-persistant, water- and air-permeable climate membrane to the carrier strip provided with the cuttings in such a manner that at least the region of each cavity of the carrier strip that is associated with the cutting base is surrounded by the climate membrane, arranging the carrier strip provided with the climate membrane in a rooting station and leaving the cuttings to root for a predetermined period of time, with regular misting, and at the end of the predetermined rooting period, dispatching the carrier strip with the rooted cuttings for further processing, or separating the carrier strip into sections each having at least one rooted cutting and dispatching the sections for further processing.

A method of increasing interspace among plant containers. The method comprises: providing a set of plant containers, the set comprising first and second plant containers; arranging the first plant containers in a first structured grid formation along a horizontal plane; and arranging the second plant containers in a second structured grid formation along said horizontal plane, whereby when viewed from above the first and second plant containers are alternatingly arranged in a joint structured grid formation in a first area. The method comprises, for increasing the interspace among the plant containers, mutually simultaneously moving the second plant containers in their second grid formation away from the first plant containers in a vertical direction and subsequently placing the second plant containers in a second area.

A plant growing vessel includes an impervious outer vessel, a cover, a first permeable membrane, a nutrient chamber, and a pocket. The impervious outer vessel includes an inert substrate in a root zone. The cover is positioned over the impervious outer vessel. The first permeable membrane is in contact with the inert substrate. The nutrient chamber includes solid nutrients. The nutrient chamber is between the cover and the first permeable membrane or between the first permeable membrane and a bottom of the impervious outer vessel, and the solid nutrients are in contact with the first permeable membrane. The pocket is configured to allow seeds, seedlings, or shoots of plants access to the inert substrate through an aperture in the cover.

A seedling nursery member for grafting according to an aspect of the present disclosure includes at least one seedling nursery unit. At least one seedling nursery unit includes a stem storage section configured to store a stem of a plant and a stem holder configured to hold the stem of the plant. At least a portion of the stem storage section of the at least one seedling nursery unit is configured to be openable so as to allow communication between an inside of the stem storage section and an outside of the at least one seedling nursery unit in a direction different from a growth direction of the plant.