Developed to transport any products, whether industrialized or not, via streams, in different geographic regions. By means of a piping circuit (1) housing distributing stations (3), in suitable points in the region of installation are formed streams driven by hydraulic pumps (2) successively installed along the length of such circuit (1). The streams are provided with conveyor capsules (4) of any industrial objects or not, capable of being carried by these capsules (4). In this way, the piping circuit (1) can be installed so as to cover large a geographic area and, for its internal rapids, to promote the transport of goods of all kinds. For control on delivery, upon stop at the predefined distribution station (3), the corresponding conveying capsule (4) shall be identified by its electronic registration. These capsules (4), after being unloaded at their distribution stations (3), are returned to the circulation by the circuit (1) and so on, thus forming an unprecedented supply system for large geographical regions.

A flow regulation system includes a sluice box that may be positioned adjacent to a fluid source. The sluice box may have a fluid urged therethrough. A regulator is slidably attached to the sluice box such that the regulator selectively restricts a flow of the fluid through the sluice box. The regulator resists being urged by the fluid flowing through the sluice box.

The present disclosure includes a hydraulic food cutter assembly having a pump, a pump discharge line, a cutter assembly a product supply tank, and a fluid transport medium comprising a method and apparatus for increasing the flow of fluid transport medium through the pump while maintaining a preselected velocity for the flow of the fluid transport medium in pump discharge line by using a frustoconical accelerator tube attached to the discharge line of the pump having a plurality of apertures through which the fluid transport medium may flow out of the accelerator tube into fluid tight housing encasing the accelerator and a throttling valve operatively attached to the fluid tight housing discharge line for regulating the pressure of the fluid medium being discharge from the pump so as to maximize fluid medium flow through the pump at a preselected pressure in the discharge line.

An item may be outfitted with a cartridge for varying a net density of the item and deposited in a body of liquid for storage. The cartridge may cause a net density of the item to exceed a density of the liquid, or to fall below the density of the liquid, and to descend or ascend within the liquid, as desired. The cartridge may also cause a net density of the item to equal the density of the liquid, and thus remain at a constant depth. The cartridge may be configured to receive acoustic signals or other forms of instructions for varying a net density of the item, and may send acoustic signals or other messages identifying a depth or position of the item. The cartridge may thus enable an item to be stored at any depth within the liquid, and be retrieved upon demand.

A method and an apparatus (1, 11, 21, 31) for moving one or more loads (5, 15, 25, 35a, 35b,45), in which method loads are moved along a channel (2, 12, 22, 32a, 32b, 49, 49) on or in fluid, wherein the channel (2, 12, 22, 32a, 32b, 49, 49) extending substantially horizontally in lengthwise direction has a cross-section, which cross-section defines an open section (13, 33a, 33b) and a closed section (14, 34a, 34b), wherein the fluid in the open section is directly in contact with surrounding air, and the fluid in the channel can flow from the open section to the closed section and vice versa through opening or openings located below the surface level of the fluid in the open section, and the load or loads (5, 15, 25, 35a, 35b, 45) are moved by floating them at least partially inside the closed section.

A method and an apparatus (1, 11, 21, 31) for moving one or more loads (5, 15, 25, 35a, 35b,45), in which method loads are moved along a channel (2, 12, 22, 32a, 32b, 49, 49) on or in fluid, wherein the channel (2, 12, 22, 32a, 32b, 49, 49) extending substantially horizontally in lengthwise direction has a cross-section, which cross-section defines an open section (13, 33a, 33b) and a closed section (14, 34a, 34b), wherein the fluid in the open section is directly in contact with surrounding air, and the fluid in the channel can flow from the open section to the closed section and vice versa through opening or openings located below the surface level of the fluid in the open section, and the load or loads (5, 15, 25, 35a, 35b, 45) are moved by floating them at least partially inside the closed section.

The invention relates to a method and a device for grouping fragile floating objects, such as floating fruits, in batches in at least one accumulation channel. An upstream portion (12) of at least one accumulation channel is supplied with objects transported by a hydraulic current as far as a downstream end of the latter provided with a retaining/releasing device for retaining/releasing the objects. The speed of the hydraulic current is adjusted so as to bring about a hydraulic superposition of the objects retained in a superposition zone of the accumulation channel against the retaining/releasing device which is closed so as to retain the objects.

The invention relates to a method and a device for grouping fragile floating objects, such as floating fruits, in batches in at least one accumulation channel. An upstream portion (12) of at least one accumulation channel is supplied with objects transported by a hydraulic current as far as a downstream end of the latter provided with a retaining/releasing device for retaining/releasing the objects. The speed of the hydraulic current is adjusted so as to bring about a hydraulic superposition of the objects retained in a superposition zone of the accumulation channel against the retaining/releasing device which is closed so as to retain the objects.

A distributor valve for a hydrocutting system. The valve automatically diverts a flow of liquid and solid food products flowing from a source to one or both of two destinations. An entry conduit receives the suspended food products in liquid, and an angled plate deflects the food products downwardly. The food products and liquid enter a drum that is perpendicular to the entry conduit, causing rotational circulation in the drum. The food products and liquid flow into one or both of two longitudinally opposite outlets, depending on whether the path downstream of the outlets is flowing. Upon actuation of a valve on one side, or essentially complete blockage of one side, the fluid and products flow to the other side automatically. No moving parts are needed in the valve to change the flow path; the only change is to the flow downstream, which automatically affects the flow in the valve.

A distributor valve for a hydrocutting system. The valve automatically diverts a flow of liquid and solid food products flowing from a source to one or both of two destinations. An entry conduit receives the suspended food products in liquid, and an angled plate deflects the food products downwardly. The food products and liquid enter a drum that is perpendicular to the entry conduit, causing rotational circulation in the drum. The food products and liquid flow into one or both of two longitudinally opposite outlets, depending on whether the path downstream of the outlets is flowing. Upon actuation of a valve on one side, or essentially complete blockage of one side, the fluid and products flow to the other side automatically. No moving parts are needed in the valve to change the flow path; the only change is to the flow downstream, which automatically affects the flow in the valve.