A device is disclosed including a pot stand configured to hold a plant within a pot. The device includes a first platform configured to hold the pot and to permit runoff water from the pot to drain through the first platform and a second platform rigidly attached below the first platform holding a removable runoff collection container collecting water from the first platform, wherein the runoff collection container is removable without moving the pot.

The present invention provides a plant transplanting device that achieves rapid and stable transplantation with a simple structure and at low cost, prevents damage to the plants, and can be automated easily. A plant transplanting device 100 that transplants a seedbed B from a plant holder 110 to a growing pallet 120 includes a holder holding mechanism 130 for holding the plant holder 110, a pallet holding mechanism 140 for holding the growing pallet 120 above a holder holding position in which the holder holding mechanism 130 holds the plant holder 110, and a push-up mechanism 150 for pushing the seedbed B held in the holder seedbed-holding hole 111 upward so as to insert the seedbed B into the pallet seedbed-holding hole 121.

A device for robotic transfer of a plantlet from a plantlet holder is provided, the device comprising an opener for opening of the plantlet holder wherein the opener comprises an actuator component for connection to a robotic tool head. Related systems, kits, and methods are further provided.

[Problem]

Provided is a continuous assemblage of pots for continuous transplanting capable of handling a seedling crop that requires a wide interval between plants, facilitated in manufacture, and reduced in manufacturing cost, and a method for manufacturing the assemblage.

[Solution]

A link piece 3 is formed by folding back both sides in a width direction of a strip-shaped sheet onto an identical face by one-sixth of a width of the sheet, using a water-soluble adhesive 21 to attach folded back inner faces, folding back the sheet onto an opposite side of the folding back by a width same as the folded back width, and using the water-soluble adhesive 21 to attach folded back inner faces. A continuous piece 13 is formed by arranging the link pieces 3 in a stagger pattern in a direction in which first folded-back portions 3a are opposed, and attaching both side end portions in the width direction of the first folded-back portion 3a in one link piece 3 to the first folded-back portion 3a of the opposed other link piece 3 using a non-water-soluble adhesive 23. An individual pot 11 is formed between the first folded-back portions 3a of the mutually opposed link pieces 3. In a transplantation of the individual pot 11, by expanding the link piece 3, the length between the individual pots 11 is increased, thus allowing handling a seedling crop that requires a wide interval between plants.

A tractor suspension type automatic transplanting machine for plug tray seedlings includes land wheels, a machine frame, a three-point linkage, a seedling pickup mechanism, a plug tray conveying device, a plug tray recovery device, seedling separating and planting devices driven by land wheels, and a watering device. Through front and rear drive cylinders, the seedling pickup mechanism is driven to move front and back to pick up seedlings above plug trays and release seedlings above a seedling guide device. Juxtaposed left and right seedling pickup modules in the seedling pickup mechanism are driven by left and right drive cylinders, to move left and right and pick up seedlings after combing, and to release seedlings after separating towards left and right. Plug trays fall onto a plug tray conveyor belt of the plug tray recovery device and slides into a plug-tray-recovery stacking box.

A high throughput system for depositing seed into germination wells of a germination tray. The system comprises a seed distribution subsystem, and an individual seed transfer subsystem structured and operable to transfer individual seeds from wells in a seed storage tray to the seed deposition subsystem. The system additionally comprises a bulk seed transfer subsystem structured and operable to singulate a plurality of bulk seeds and transfer each singulated seed to the seed deposition subsystem, wherein the seed distribution subsystem structured and operable to receive seeds from the individual seed transfer subsystem and the bulk seed transfer subsystem, and deposit the seeds into wells of the seed germination tray.

A process for line production of plant growth medium pots or bags with a closed bottom end includes the steps of: i) continuously folding the free end of a continuous length of water and air permeable sheet material into a sheet material tube around and beyond a free end of a growth medium feeding tube; ii) forming a first sealing in the sheet material tube; iii) filling the sheet material tube with a measured amount of growth medium; iv) forming a second sealing in the sheet material tube; v) separating the part of the sheet material tube positioned downstream from the second sealing to form a first plant growth medium pot or bag with a closed end, repeating as needed to form a plurality of plant growth medium pots or bags.

Provided is a transplanting device for performing transplanting between a plurality of culture medium boards cultivating a plurality of plants planted in an aligned manner. The transplanting device includes a transplanting mechanism for transplanting the plants, where the transplanting mechanism performs alternately a step of arranging plants having been arranged in a grid form on a culture medium board of a transplanting source, into a zigzag form on a culture medium board of a transplanting destination, and a step of arranging plants having been arranged in a zigzag form on a culture medium board of a transplanting source, into a grid form on a culture medium board of a transplanting destination.

An apparatus having an automatically adjustable pot seedling feed rate and a method therefor are provided. In some embodiments, the apparatus comprises a pot seedling scooper, a conveyance unit, a detection sensor, a controller, a seedling sorting unit, side panels, and brackets. The conveyance unit comprises a servomotor, a transmission shaft, a conveyor belt, a tension shaft, and a bearing. The seedling sorting unit comprises a seedling sorting rod, a reset spring, a guide post and a support seat.

Provided are a plant management system and a plant management method, which do not entail a substantial workload, cost, construction period, or installation space; enable a system to be easily constructed, altered and expanded; have a small maintenance load; enable processing systems to be distributed and arranged in geographically separate locations and in locations where connecting the processing systems is not easy; and are capable of preventing the occurrence of large-scale problems. A plant management system 100 has: a plurality of processing systems 140, 150; and memory tags 112, 122, wherein processing systems 140, 150 include reader-writers 142, 152, 153 and processing devices 141, 151, and, by writing plant management data into the memory tag 112 by means of the reader-writer 142 and then reading the plant management data by the reader-writer 152 of the processing system 150, the plant management data is transferred between the processing systems 140, 150.