The present invention provides a dual layer planter liner having: (a) a first fibrous layer having an interior surface and an exterior surface, the first fibrous layer is formed into a pot for emplacing a planting medium and/or plant therein. The first fibrous layer is formed from a first fibrous material; and a second fibrous material adhered onto the exterior surface of the first fibrous layer. The adhered second fibrous material forms a second fibrous layer. The present invention, also, provides a method for making the dual layer planter liner hereof.

An assembly well irrigation system for environmentally friendly water conservation includes: at least one well, having a ventilation tube inserted into the top of the well, an absorbent element covered onto the bottom and outer wall of the ventilation tube and filled up in an opening between the top of the well and the ventilation tube, and a float contained in the ventilation tube; and at least one water supply bottle, having a cover installed to the opening of the water supply bottle, and the cover having a fixed tube passing to the cover and a penetrating hole formed on the cover, and the penetrating hole having a movable tube capable of moving up and down for adjustment, and the water supply bottle being inverted, such that the cover is installed to the well, and the fixed tube, the movable tube and the ventilation tube are situated in the well.

The present invention relates to a watering bag for automatic supply of water to plants, such as indoor plants. The watering bag comprises a water inlet region, a water reservoir, and a water outlet region, wherein the water inlet region comprises an opening for leading water to the water reservoir, and wherein the water outlet region comprises a friction inducing arrangement for leading water from the water reservoir to the surroundings in a controlled manner.

A top feeding wicking apparatus and system for dispersing liquid through plant growing medium is disclosed. The apparatus includes a geometrically shaped container having a bottom, an inner wall, and an outer wall forming a channel therearound for receiving liquid therethrough. Container has a center opening for receiving a plant and container bottom is configured with at least one hole for receiving liquid therethrough. A geometrically shaped lid having a top, an inner wall, and an outer wall forming a channel therearound from an underside of lid is configured to be adjoined to container. A geometrically shaped base layer and wicking layer each having an inner wall and an outer wall and a center opening for receiving plant with a longitudinal opening extending therefrom to outer wall to allow placement of base and wicking layers on plant or to allow removal of base and wicking layers from plant. Container with lid is configured to set atop base layer and wicking layer such that liquid is dispersed through plant growing medium.

A top feeding wicking apparatus and system for dispersing liquid through plant growing medium is disclosed. The apparatus includes a geometrically shaped container having a bottom, an inner wall, and an outer wall forming a channel therearound for receiving liquid therethrough. Container has a center opening for receiving a plant and container bottom is configured with at least one hole for receiving liquid therethrough. A geometrically shaped lid having a top, an inner wall, and an outer wall forming a channel therearound from an underside of lid is configured to be adjoined to container. A geometrically shaped base layer and wicking layer each having an inner wall and an outer wall and a center opening for receiving plant with a longitudinal opening extending therefrom to outer wall to allow placement of base and wicking layers on plant or to allow removal of base and wicking layers from plant. Container with lid is configured to set atop base layer and wicking layer such that liquid is dispersed through plant growing medium.

A top dripping and bottom wicking assembly and method of operation feeds a reservoir that controllably drips liquid nutrient solution from above a plant, and also uses capillary action of a planar wick member to draw the liquid nutrient solution into a plant growing medium and plant roots. The assembly works to controllably drip the liquid nutrient onto the plant through sized and dimensioned drip holes that form in the reservoir, while simultaneously dispersing the liquid nutrient solution through a planar wick member to disperse liquid nutrient solution to a plant growing medium and the roots of the plant. Stakes hold the reservoir above the plant. The wick member is flat and forms a central opening to allow passage of the plant. A plant support member retains the plant in an upright position. The plant support member forms wicking holes to enable passage of liquid nutrients from the wick.

A top dripping and bottom wicking assembly and method of operation feeds a reservoir that controllably drips liquid nutrient solution from above a plant, and also uses capillary action of a planar wick member to draw the liquid nutrient solution into a plant growing medium and plant roots. The assembly works to controllably drip the liquid nutrient onto the plant through sized and dimensioned drip holes that form in the reservoir, while simultaneously dispersing the liquid nutrient solution through a planar wick member to disperse liquid nutrient solution to a plant growing medium and the roots of the plant. Stakes hold the reservoir above the plant. The wick member is flat and forms a central opening to allow passage of the plant. A plant support member retains the plant in an upright position. The plant support member forms wicking holes to enable passage of liquid nutrients from the wick.

The potted plant system of the present invention uses the space between the inner and outer pots as a reservoir for water. The water reservoir acts passively to transport water into the spoil of the inner pot which is subsequently used by the potted house plant. The reservoir is filled by over watering the inner pot and allowing the excess water to pass through the apertures within the inner pot. Passive transport of water from the reservoir to the soil occurs as the water saturation of the soil decreases. As a result, the soil and the potted plant remain hydrated for longer period of time as the reservoir continuously replenishes the water. The water within the reservoir can be drained through a quick connect sliding valve located on the outer pot. The quick connect sliding valve is either placed above another water receptacle or is fitted with a hose that transports the water to a drain.

The potted plant system of the present invention uses the space between the inner and outer pots as a reservoir for water. The water reservoir acts passively to transport water into the spoil of the inner pot which is subsequently used by the potted house plant. The reservoir is filled by over watering the inner pot and allowing the excess water to pass through the apertures within the inner pot. Passive transport of water from the reservoir to the soil occurs as the water saturation of the soil decreases. As a result, the soil and the potted plant remain hydrated for longer period of time as the reservoir continuously replenishes the water. The water within the reservoir can be drained through a quick connect sliding valve located on the outer pot. The quick connect sliding valve is either placed above another water receptacle or is fitted with a hose that transports the water to a drain.

The potted plant system of the present invention uses the space between the inner and outer pots as a reservoir for water. The water reservoir acts passively to transport water into the spoil of the inner pot which is subsequently used by the potted house plant. The reservoir is filled by over watering the inner pot and allowing the excess water to pass through the apertures within the inner pot. Passive transport of water from the reservoir to the soil occurs as the water saturation of the soil decreases. As a result, the soil and the potted plant remain hydrated for longer period of time as the reservoir continuously replenishes the water. The water within the reservoir can be drained through a quick connect sliding valve located on the outer pot. The quick connect sliding valve is either placed above another water receptacle or is fitted with a hose that transports the water to a drain.