NO320949B1 - Ceiling device for drilling rig for handling drill bits - Google Patents

Abstract

A lifting device (7) is provided for a drilling machine which comprises a substantially horizontally arranged articulated arm (8), a substantially vertically arranged auxiliary arm (9) which is length-adjustable vertically, control device (10), hydraulic motor (13) and magnet (14 ). The lifting device (15) advantageously comprises an extension (16) and an articulated suspension (15) for the magnet (14). A lifting device (7) for a drilling machine is provided which comprises a substantially horizontally arranged articulated arm (8), a substantially vertical arranged auxiliary arm (9) which is length-adjustable vertically, control device (10), hydraulic motor (13) and magnet (14). The lifting device (15) advantageously comprises an extension (16) and an articulated suspension (15) for the magnet (14). A method and device for algae production where a fluid comprising algae is in growth containers (34) made of plastic foil. A CO2-containing gas is supplied, and the gas is circulated through the growth vessels (34) via a gas treatment apparatus (24).

Description

DEVICE FOR ALGAE PRODUCTION

This invention relates to a device for algae production. More specifically, it concerns a device for algae production where gases are circulated through an at least partially liquid-filled container, where the container is designed to exhibit growth-promoting features, for example by being transparent. The method is equally suitable for the production of so-called microalgae both on land and in the sea.

The need for microalgae is constantly increasing in aquaculture, as a health food for humans and as a supplement for animals. In aquaculture, microalgae are used directly or indirectly as feed for fish and shellfish. It is, for example, advantageous to feed cod fry with microalgae during a period when the cod fry are particularly sensitive to environmental conditions. Shell production also appears as an industry that will need forage of this kind. Within poultry production, microalgae are already used as supplements. Microalgae are also used for a number of purposes in research and industrial activity.

According to known technology, microalgae are produced in transparent tubes and containers which are placed in greenhouse-like buildings. This is done to make the best possible use of the sunlight, while the temperature in the water must be able to be controlled. Production facilities of this kind are relatively expensive and require space.

It has been proposed to use welded together plastic foil as containers to reduce construction costs in connection with algae production. US patent 5534417 thus describes a method for producing microalgae where the microalgae are located in pockets made of plastic material, and where gas is bubbled into the pockets.

GB document 2192195 describes a bioreactor where the biomass circulates through a gas exchanger where gas is added via pipes that are equipped with microscopic openings through which the gas is diffused into the biomass.

Carbon dioxide, C02, is an important ingredient in the microalgae's nutrient supply and C02 is therefore mixed into air before it is bubbled into the pockets. However, only a small part of the bubbled C02 is taken up by the algae in the pocket. The excess C02 flows out to the atmosphere. This common practice according to known technology involves a cost-driving and unnecessary waste of C02.

The purpose of the invention is to remedy the disadvantages of known technology.

The purpose is achieved according to the invention by the features indicated in the description below and in the subsequent patent claims.

A gas mixture comprising oxygen, 02 and C02 is circulated through a number of interconnected closed growth containers. The C02 that is not taken up by algae in the growth containers is extracted to a gas treatment device which is designed, among other things, to be able to regulate the proportion of C02 in the circulating gas, before the gas is led back into the growth containers.

The circulating gas mixture is also regulated with regard to 02 to ensure that the 02 level does not exceed critical values for the microalgae.

In a preferred embodiment, the containers are made from a double plastic foil where the two foil layers are welded together along their circumferential edge and along parallel lines so that the foil layers form a foil bag. The welding along the parallel lines is finished at the ends of the lines at a distance from the edge weld of the foil. The spaces between the parallel welding lines thus communicate with each other at their end portions.

By hanging the welded foil bag in a stand in such a way that the parallel lines assume a vertical direction, the space in the foil forms a number of growth containers which are closed in relation to the surroundings.

A tube for supplying and draining liquid is connected to the foil bag. There is also a supply and an outlet for the gas that is circulated through the foil bag. It is advantageous that the gas is supplied via a perforated tube located in the lower part of the foil bag. The gas can thereby be bubbled through the growth containers and up to the upper part of the foil bag, where it is extracted to the gas treatment device.

The mentioned foil bag can advantageously be supplied with further foil layers where, for example, a fluid can be circulated for temperature regulation of the liquid in the growth containers, or that the light spectrum of the algae is regulated by means of a fluid located between adjacent foil layers.

It is also possible to temporarily store the gas in a container before it is processed and returned to the foil bag.

In an alternative embodiment which is suitable for microalgae production in the sea, the welded foil bag is placed horizontally floating in the water surface. A perforated supply channel for gas is arranged along each grow container in the lower part of the grow container. Gas is withdrawn from the upper part of the growth containers, which is full of gas.

The method and device according to the invention facilitates large-scale production of algae where investment and operating costs are relatively modest compared to known technology.

In what follows, a non-limiting example of a preferred method and embodiment is described which is visualized in the accompanying drawings, where: Fig. 1 shows a side view of a foil bag which is connected to a gas treatment apparatus; Fig. 2 shows a section I-1 in fig. 1; Fig. 3 shows a corresponding section as in fig. 2 where the foil bag is provided with additional foil layers; and Fig. 4 shows a side view of a foil bag placed in the water surface; and

Fig. 5 shows a section IV-IV of the foil bag in fig. 4.

In the drawings, the reference number 1 denotes a foil bag comprising a first foil 2 and a second foil 4. The foils 2 and 4 are welded together along their circumferential edge 6 and along parallel lines 8. The welding along the parallel lines 8 ends at a distance from the circumferential edge 6.

The foil bag 1 is held in a mainly vertical position by means of suspension hooks 10 which complementarily fit into suspension openings 12 in the fastening part 14 of the foil bag 1.

A first manifold 16 is formed at the upper part of the foil bag 1 in the area above the parallel welding lines 8 and is delimited by the peripheral edge 6. In a similar way, a second manifold 18 is formed at the lower part of the foil bag.

A first pipe 20 is via a valve 22 connected to the second manifold 18.

A gas processing apparatus 24 communicates with the first manifold 16 by means of a second pipe 26, and with a perforated pipe 28, which is located in the second manifold 18, via a third pipe 30. The gas processing apparatus 24 can in a manner known per se include the following components not shown: a Unitronic PLC control unit that controls a valve to open and close for C02 gas based on readings from a Valsala GMT 222 sensor.

The perforated pipe 28 extends in the longitudinal direction of the second manifold 18.

The foil bag 1 is filled with liquid, which, among other things, contains algae, via the valve 22 and the first pipe 20 up to a level 32. The spaces between the parallel lines 8, and between the parallel lines 8 and the vertical parts of the peripheral edge 6, now form growth containers 34, see fig. 2.

Gas that has been corrected to the desired content of 02 and C02 and possibly other gases flows from the gas processing apparatus 24 through the third pipe 30 and to the perforated pipe 28 from where the gas bubbles up through the growth containers 34.

Gas that flows out of the growth containers 34 and into the first manifold 16 flows on to the gas processing apparatus

tet 24 via the other pipe 26.

The growth containers 34 together with the first manifold 16, the second manifold 18, the gas treatment apparatus 24, a second pipe 26, a third pipe 30 and the perforated pipe 28 form a circulation circuit.

In another embodiment, see fig. 3, the foil bag 1 is provided with further foil layers 36, 38 which are arranged for the circulation of temperature and color regulating fluid.

In a further embodiment, see fig. 4 and 5, the foil bag 1 is placed floating in a water surface 40. In this embodiment, perforated tubes 28 are mounted along the lower part of each growth container 34. The gas flows from the perforated pipes 28 through the water in the growth container 34 and up to a gas pocket 42 from which the gas flows out via the second pipe 26.

The elements 20, 26, 28 and 30 are referred to as pipes, but in the practical embodiment can be made up of, for example, integrated channels in the foil bag, hoses or other hollow elements.

Claims (7)

1. Device for algae production comprising growth containers (34) which are made of plastic foil (2, 4), characterized in that the cavity (16, 18, 34) of the plastic foil (2, 4) forms part of a closed system comprising a gas treatment device ( 24), and where the gas treatment device (24) is designed to at least adjust the C02 content in an excess gas that is collected, before the gas flows into the growth containers (34). 2. Device according to claim 1, characterized in that a foil bag (1) comprises at least two growth containers (34). 3. Device according to claim 2, characterized in that the growth containers (34) communicate with at least one of a first or a second manifold (16, 18). 4. Device according to claim 2, characterized in that the growth containers (34) at their lower part communicate with a perforated pipe (28). 5. Device according to claim 4, characterized in that the perforated pipe (28) communicates with a gas treatment device (24). 6. Device according to claims 3 and 5, characterized in that the gas treatment device (24) communicates with the first manifold (16). 7. Device according to claim 1, charac- characterized in that the growth containers (34) together with a first manifold (16), a second manifold (18), the gas treatment apparatus (24), a second pipe (26), a third pipe (30) and at least one perforated pipe (28) constitutes a circulation circuit.