FR2847571A1 - Seawater desalination system employs deep-sea geothermal heat exchanger producing hot brine, with evaporation nozzles and condensers in reservoir at surface - Google Patents

Abstract

Cold seawater is sent down pipework to a heat exchanger at great depth, returning via a riser at over 100degreesC. This terminates at a reservoir with vaporization nozzles above condensers. These condense the vapor. Low in the reservoir, brine flows out through a system preventing vaporization on reaching atmospheric pressure. The brine is returned directly to the sea.

Description

DESALINATION OF SEA WATER WITH A VIEW TO

PRODUCE FRESH WATER

BY A GEOTHERMAL PROCESS

  The system used is that of evaporation. It is a proven, safe, efficient system that consumes a lot of energy. If the latter can be obtained at a very low price, or even be free, the system becomes by far the most efficient there is. i The proposed Patent is simple in spirit, safe in principle, flexible in its operation, benefiting with regard to the drilling part of the expression of tankers in this area. Since the energy used is geothermal energy, the price of the fresh water produced comes down to: investment, upkeep, maintenance and operating costs, a summary of which will be given at the end of the text. is described below with reference to the drawings, tables and

calculation notes attached.

  Figure 1 gives an overview of the stated principle, Figure 2 gives a schematic representation of the need for a buffer cavity. Figure 3 shows the principle of the hot water arrival in the basin located at the top of the installation which produces the steam to pass to

fresh water and drain off the brine.

  Figure 4 shows a detail of the sprinklers and the possibility of intervening

  during operation without disturbance of the latter.

  Drawing 5 shows the detail of evacuation of the brine which must be

  evacuated without risk of vaporization.

  Table 1 allows the determination of the cost price of fresh water.

  The attached calculation sheet shows the technical feasibility of the system, in particular the possibility of raising the hot water while ensuring that it only loses a small part of its temperature.

  so as to respond to the principle laid down.

  Reminder of the operating principle: salt water is taken from the sea surface or at a certain depth descends through a

  tube to a depth of 4000 m or less if possible.

  We know that the Earth's temperature increases by about 3 degrees every 100 meters with sometimes significant differences 100C per meter in Alsace. At this depth, the temperature will oscillate between 115 and 120 degrees. A riser pipe will supply the basin with hot water at a temperature higher than the vaporization temperature. Consequently, the airing by the nozzles is in the form of vapor. The salt is deposited at the bottom of the tank and flows in the form of

brine in seawater.

  In order to make the best use of geothermal energy, you must try to have the lowest speed on the descent and the fastest on the ascent to store calories on one side, lose as little as possible on the other. In this configuration, it is possible to produce in addition to electrical energy: by having a turbine in the descent using the steam at the outlet to drive a turbine while retaining the possibility of obtaining fresh water . Nothing prohibits if

necessary all electric.

  To meet the operating conditions and in particular a flow rate of approximately Im3 seconds, a simple circulation is not enough. Indeed, the conductivity of the soil, about 2 kcal h / m does not respond

  directly to calorific needs.

  It is therefore necessary to create from scratch a buffer tank as shown on Plate 2, the capacity of which will be such that the passage, or the removal of one m3 per second will be entirely compensated by the calorific contribution of the walls. The calculation shows that a capacity between 4000 and 6000 m3 allows operation without any disturbance on the temperature, for information, for 4000m3, if the tank was spherical, its radius would only be 10 meters. In fact, the shape of this tank will be close to a potbellied bean which increases the exchange surface. Drawing 1, which represents the freshwater production circuit, shows that salted seawater enters the descent via the supply tube, meets a valve 2 intended to regulate filling and can serve as a stop valve. . A pump 3 makes it possible to "push" the water so as to bring the hot water up to the tank 10. In its path, the water passes through the buffer tank described later, reaches its vaporization temperature, in this

  configuration, from 1150 to 1200 C. This water goes back to tank 10.

  The water is then at a temperature slightly lower than that of the tanks. This tank is equipped with nozzles 11 which allow the hot water to

  exit to the atmosphere where it immediately turns into vapor.

  This vapor condenses on contact with the condensers 14. The fresh water thus produced is recovered by recovery chutes 14 or any other system for recovering runoff. Evaporation causes an increase in the salinity of the tank water. As a result of the density ratio, this water in the form of brine is found at the bottom of the tank and is discharged continuously by the weir 7 which will be described later. Drawing 3 and 5 Note that this system lends itself to the purification of brackish water, rivers, lakes, etc ... the impurities are treated

like brine.

  The production envisaged and as an example of the order of m3 of fresh water per second is subject to a certain number of constraints. A temperature indicator 4 allows, depending on its indications, to vary the flow rate so as to comply with the operating conditions. A salinity indicator 5 makes it possible to compare the

  salinity from the bottom to that of the incoming water.

  More elaborate automatisms are envisaged but their description

  operating aid does not change the principles. They are therefore also so variable, that to describe them would bring nothing but a

  weighting of the text, so we will not.

  The principle being defined, it is important to ensure its feasibility, its cost of realization, its cost of exploitation, its duration, the price of

  fresh water being linked to all of its parameters.

2847571

FEASIBILITY:

  The drilling methods developed by the oil companies authorize

drilling at these depths.

  The heat exchange chamber which here acts as a temperature buffer will have its volume linked to the flow of water that we want to recover. The production cost is taken from the book by Mr JP NGUYEN of

  the National School of Petroleum and Engines.

  This work allows an approach of the price and execution times.

  By updating the 1993 prices, we will retain an average price of

  4000 F / ml to which is added the casing and cementing operation.

  In the principle that interests us, the downpipe will have the largest possible diameter because it will also be used to raise the cuttings from the clearing house. In the example chosen: im3 second, this diameter could be 50 cm and its construction be done in concrete according to the principle used by tunnel boring machines. If we remember that the covering represents the price of drilling appreciably, we would arrive at a total cost of 8000 f per linear meter. Which in the case of a depth of 4000 m, would represent 64 million French francs. Drawing 3 shows the key system of the patent. The hot water is supplied by the collector 1, a valve 2 allows the isolation of this collector, a distribution collector 3 allows a multi-distribution of the hot water in the tank. The pipes are all fitted with isolation valves. The brine is discharged through the orifice 4, the thickness of the brine 6 is known at all times by the brine thickness recording indicator, the water temperature is known by the temperature recording indicator (7 ). The hot water tank (8) will have much smaller dimensions than the buffer tank. The nozzles are mounted in groups: distributor -9) which will be seen in detail later. A filter (10) separates the water

  from the hot water tank arriving at the nozzle (11).

  The fresh water evacuator (12) returns this water to the appropriate tanks. The condensers are symbolized by the vertical lines (13).

DETAIL ON THE JETS :.

  The maintenance of the latter, cleaning of the individual filters, unblocking of the sprinkler heads, must be done without the operation being interrupted. The sprinklers are therefore assembled per group and the number of groups will be greater than necessary so as to have the constant possibility of maintaining sprinklers without modifying the production. Plan 4 shows the principle adopted. A box (1) containing hot salt water, an isolation piston (2) acts as an intake valve. A valve (3) controlled by this piston introduces a double sealing factor. A seal (4) ensures a perfect seal during long-term intervention. The piston control (5) is shown diagrammatically, it can be manual or hydraulic or both. The nozzles (6) are removable - universal connection at the touch of a button. Drawing 5 shows the brine drainage system. Particular attention is paid to this evacuation because a simple release into the atmosphere would result in vaporization. In the present case, the brine is passed through a cylinder 4 surrounded by a cooling system 3 which makes its temperature drop below 100 degrees, which eliminates any risk of evaporation, the evacuation then takes place through the container 5, Note that if the basin is not very above sea level, a simple dip tube in this

the latter would do the trick.

! DETAILS ON CONDENSERS |

  These condensers will be cooled by seawater drawn to a great depth, which avoids the use of refrigerant. The

  condensers will be of the planar or cylindrical type as required.

  The enclosure cover will be continuously cooled (except in rainy weather) so as to allow condensation of the vapors not treated by the condensers. The condensation water will be recovered in drains discharging into evacuation collectors.

| STAFF EXPENDITURE: |

  It is considered that 4 operating operators, 2 maintenance specialists, 3 maintenance technicians, 1 administrative manager and a

  secretary and a storekeeper for a total of 12 people.

  By retaining a price of 20,000 francs per person, the annual expenditure

is 2,880,000 Francs.

  Energy expenditure (pumps and lighting) is considered to amount to 2,200,000 Francs, replacement expenditure to 1,000,000 o

  a total of 5,080,000 Francs annually, or 774,000 Euros.

INVESTMENTS: |

  Main pipeline Environment Pumps Signaling lighting Protection and access to operations Platform if necessary Total investment Financial costs Total investment Expected duration of the installation Expenses reduced to the year Operating expenses Annual accounting expenses

: 64M

: 64M

: 1M

: 1M

: 2M

: 2M

: 134 M F

: 40M 174 M: 30 years: 174M out of 3

= 5800000

: 5080000

: 10880000

In M of Euros

9.757 M

9.757 M

0.152 M

0.152 0.305 0.305, 430 6.010

26.528

0 years

F 0.884

F 0.774

F 1,658

9 2847571

COST OF RETURNING M3 OF FRESHWATER

  We use a flow rate of 1 m3 / s which gives a flow rate of 31,104,000 m3 / year. The price per m3 per year therefore stands at 10,880,000 F / 31,104,000 = 0.3497 F rounded to 0.35 F or 0.053 Euros. 1 0

TABLE 1

O

  Determination of the cost price per m3 of fresh water.

  These prices may vary depending on the type of installation. In the table below are the prices per m3 in the case of two light installations capped at 30-40 million m3 / year, heavy installation starting at 550,600 million m3 / year.

  The latter allows increases in production with moderate additional investments and in addition allows the production of electrical power of comfortable powers, for example from 40 to 400 mw for the "low end".

  at 40 million Min 550 million m3 / year m3 / year Investments (euros) 20.43 10 (6) 510 10 (6) Financial costs 6.010 (6) 304 10 (6) Recharge included invest 204 10 (6) Duration 30 years 50 years Total disbursements 26.44 (6) 1,018 10 (6) Disbursements carried over to the year 26.44 () 20.36 10 (6) Total expenses 884,000.00 20.36 10 (6) operating costs 774,000, 00 3.6 10 (6) Accounting expenses 1 658 000.00 23.9 10 (6) annual Debit mr) ini annual 32 10 (6) 550 10 (6) m PR M3 0.053 euros 0.0434 euros

(0.347 FF) (0.284 FF)

  i_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ l 1 '

CALCULATION SHEET

  1) Determination of heat exchange surfaces Application at a flow rate of 1m3 / s Heat capacity of water 4.18 kj / kg / 0C Heat capacity of the soil 2 kj / kg / 0C Ground conductivity 8 Kj / h / m 0C Soil density 2000 kg / m3 Energy required for 1m3 of water from 20 to 120'CW = mcT = 1000x4.18x100

418,000 KJ

  Energy availability per m3 soil W = m.c. T = 2000x2x120

= 480,000 KJ

  Hourly availability per m2 480,000 x 8

= 3,840,000 KJ

Available energy / second / m

3,840,000 / 3,600

= 1,060 KJ

  Area required 418,000: 1,060,394 m2

  This surface could be that of a sphere or a cylinder. In the case of a sphere, we would have a radius of 5.6 m or a volume of 735 m3. In practice, this capacity will be multiplied by 5 or 6 to take account of the vagaries of soil conductivity.

  1 2 | DETERMINATION OF THE WATER TEMPERATURE AT THE DETERMINATION OF THE JET SPRAY l It is shown that an established regime has substantially T = W Ialphax S Alpha s T = radiation coefficient = exchange surface in m2 = OC temperature Here, it is necessary to take into account the travel time and the speed, We will then have: T = (W / Alpha.S) VT Any calculation made for a diameter of 0.2 m a section of 0.0314 m2 a speed of 32m / s a 4000m tube

  We can see that the temperature drop is 0.850C less than 1C.

  This is to be compared with the readings made on oil wells in Kuwait at 1800m: T = 115'C 0 at the outlet: T = 1140 / 1150C

except for measurement errors.

Claims (9)

! CLAIMS: |   1) Seawater desalination system characterized in that it comprises the following elements: A double pipe for the descent of cold seawater passing through an exchange pocket located at great depth, raising of hot water to a temperature above 1000C ending in a tank fitted with a spray nozzle, above the condensers responsible for condensing the vapor, in the lower part of the tank, a flow of brine through an adequate system to avoid vaporization by setting at   the atmosphere. This brine returns directly to the sea.   2) Desalination system according to claim 1 characterized in that a grid or more grids with fine meshes are mounted on the jets in order to protect the jets from particles in suspension in salt water which could either block them or reduce their debit. This system also allows the treatment of brackish water. 3) Desalination system according to claim 1 characterized in that the vapor produced, free of salt, is transformed into water   gentle by condensation on cold walls.   4) Desalination system according to claim 3 characterized in that the spray nozzles, mounted in groups, are accessible for maintenance, replacing without interruption of the fresh water production.   5) Desalination system according to claim 3 characterized in that the capacitors are supplied directly with sea water drawn to a depth such that the temperature of condensation is ensured.   6) Desalination system according to claim 1 characterized in that the brine from the bottom of the tank flows through an assembly prohibiting spraying.   7) Desalination system according to claim 1 characterized in that the sections of the pipes lowering cold water raising water are different.   The speed of cold water is lower than the speed of hot water. Cold water can thus store calories on the way down and   hot water lose as little as possible on the climb.   8) Desalination system according to claim 1 characterized in that it comprises a turbine for supplying electricity, driven by the difference in densities: - falling cold water - rising hot water and also by the differences in section between the pipes up and down.   9) Desalination system according to claim 7 characterized in that it comprises a steam turbine in a hydraulic turbine on the desalinated water outlet in view of producing   electricity combined with desalination.