NL7808199A - Reversed osmosis concn. - of whey or milk or whey ultrafiltration permeate in two steps at different temps. - Google Patents

Abstract

Whey, or an ultrafiltration permeate from milk or whey, is concentrated by reversed osmosis in two steps, with the temp. in the first step is not 10 degrees C higher than in the second step. Pref., the temps. are 30 degrees C in the first step, and 10 degrees C in the second step. Concn. in the first step is partic. carried out to a concn. factor of 1.4-1.7. At 30 degrees C the flux (amt. of water removed, in litres/m2 of membrane surface/hour) at concn. factors of 2 and of 3 is much lower than the corresp. flux values at 10 degrees.

Description

Applicant: Company Foundation of the 'Netherlands Institute for Dairy Research in Ede

Authorized representative: none

Priority invoked: none

Short designation: Method for concentrating whey or ultrafiltration permeate from whey or milk

It is known that reverse osmosis offers special advantages over concentrating certain liquids over conventional evaporation; this applies in particular to whey and to the permeate of whey or milk obtained by ultrafiltration.

5 In reverse osmosis, the permeate flux (the amount of water removed in 2 liters per m membrane surface per hour) is an important feature. The size of the flux largely determines the economy of the process. An average flux is calculated, which is calculated from the amount of water removed during the entire duration of the process, and an instantaneous flux, which is calculated from the amount of water removed at a given moment of very short duration. The magnitude of the flux depends on the properties of the membrane, on the composition of the fluid involved, and on the process conditions used. The main process variables are the temperature, pressure and fluid velocity along the membrane.

An important property of the cellulose used in reverse osmosis

Acetate membranes is that the permeability to water increases with increasing temperature.

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Since these membranes are not resistant to use at temperatures above 35C, it is recommended to perform the reverse osmosis process at approximately 30C.

The following results were obtained in experiments simulating the operation of a multistage, continuously operating reverse osmosis installation at 10 ° C and at 30 ° C.

Run a was performed in a one-stage installation according to a 2 continuous system. The membrane area was 9.5 m (C.A. membrane type HF 87.5 from Wafilin). Four lots of whey were concentrated at 10 ° C to a concentration factor of 1.5, 2, 3 and 4, respectively. The liquid velocity along the 2 membrane was 2.6 m / sec. and the pressure was 3.7 - 4.0 MPa (37 - 40 kg / cm).

A constant flux level was reached after about 2 hours.

O

Test b In the same system as described under a), it was concentrated at 30 ° C

up to a concentration factor of 1.5, 2 and 3, respectively. The further conditions were the same as in test a).

Run c was performed in a non-circulation (single pass) installation, operating on the continuous system, with a membrane area of 15.2 m. This membrane was of the same type as in the previous tests.

The whey was concentrated to a concentration factor of 1.5. The liquid velocity was 2 m / sec at the inlet and 1.3 m / sec at the outlet. After about 2 hours, a nearly constant flux level was reached.

_Table A___

Concentration factor 1.5 _2_ _3_ _4_

30 a) temp. 10 ° C

instantaneous flux 19 16.5 11.5 6

b) temp. 30 ° C

instantaneous flux 27.5 6.5 5.5

C) temp. 30 ° C

instantaneous flux 22.5

The relatively greater reduction of the flux at 30 ° C at the concentration factors 2 and 3 is attributed to the precipitation of calcium phosphate in the membrane, which precipitates a clogging of the membrane. If calcium is removed prior to concentrating whey, no sharp drop in flux occurs; however, the pre-removal of calcium is a complicated process, and is not always desirable.

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According to the invention it has now been found that concentration by means of reverse osmosis of whey or of ultrafiltration permeate of whey or of milk can be successfully carried out when working in two stages, the temperature in the first stage being at least 10 ° C higher than in the second stage.

Preferably, the concentration in the first stage is carried out at 30 ° C, and in the second stage at 10 ° C. It is advantageous if in the first stage the concentration is carried out up to a concentration factor of 1.4 to 1.7.

At 30 ° C, the fluxes at concentration factors of 2 and 3 are much lower than the 10 corresponding fluxes at 10 ° C. This shows that the concentration by means of reverse osmosis, first at 30 ° C and then further concentration at 10 ° C, is very favorable.

Example I

In an installation with tubular membranes of cellulose acetate (HF 87.5) and a total membrane surface area of 9.5 m, three tests were carried out, each with 1000 liters of whey. The flow velocity in the tubes was 2.6 m / sec. and the pressure 4 MPa.

The first whey concentration test (1) was conducted at 11 ° C, the second (2) at 30 ° C and the third partially at 30 ° C (3a) and then at 11 ° C (3b). In these tests, the permeate flow was measured continuously, and the amount of concentrated whey was intermittent.

Table B shows data from the three tests in relation to the concentration factors 1.5 and 3.

_Table B_

Trial 1 Trial 2 Trial 3a Trial 3b temp. (° C) 11 30 30 11 30 conc ^ factor 1.5 time (hours) 2.05 1.23 1.25 average flux 18.0 30.0 29.5 from conc factor 1.5 to conc factor 3 35 time (hours) 2.50 4.90 2.25 average flux 13.5 6.9 15.0 total process <__ y time (hours) 4.55 6.13 3.50 40 average flux 15.5 11 , 5 20.2

Run 3, in which the two-stage process (3a and 3b, respectively, according to the invention were carried out) thus gave an important time saving.

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Example II

In an installation with two series-connected circulation stages with a 2 membrane surface of 7 m each, whey was concentrated according to a continuous system. In the first stage, the concentration was concentrated to a concentration factor of 1.5 and in the second stage to a concentration factor of about 2.5. In a first test, the temperature was kept at 29 ° C in both stages; in a second run, the concentrate after the first stage operating at 29 ° C was cooled and further concentrated in the second stage at 17 ° C.

The time in both processes was 5 hours. After stabilization of the flux (after about 1 hour), the flux values shown in Table C were measured.

Table C

Test 1 Test 2 15 stage-1 instantaneous flux 19 19 stage 2 instantaneous flux 6 15 20 The data in table C shows that cooling the concentrate between the two stages, as in experiment 2, gives a clear capacity improvement.

Example III

By ultrafiltrating 200 l of skimmed milk at 10 ° C to a concentration factor of 2, 100 l of ultrafiltration permeate (UF permeate) was obtained. This UF permeate was divided into two batches of 50 liters each. The first batch was concentrated to a concentration factor of 5 at a temperature of 10 ° C, the second batch to a concentration factor of 3.33 at a temperature of 30 ° C. In both cases, a batch system was used in an installation with DDS 990 cellulose acetate membranes and a membrane area of 1 m. Table D shows the instantaneous fluxes measured during the process for both versions.

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Claims (2)

A method according to claim 1, characterized in that the first stage concentration of the reverse osmosis is carried out at 30 ° C and the second stage concentration is at 10 ° C. 3. A method according to claim 2, characterized in that the concentration in the first stage of the reverse osmosis is carried out until the liquid is concentrated 1.4 to 1.7 times. / 7808199