Patent Publication Number: US-2004045451-A1

Title: Method for deaerating food puree, and dearerator

Description:
TECHNICAL FIELD AND BACKGROUND ART  
       [0001] The present invention relates to a method for deaerating food puree and to a deaerator. Currently, to extract juices and purees from food products, generally the product is subjected to cold trituration and subsequently heated with the purpose of effecting an enzymatic deactivation of the triturated product which then ends in a straining or refining machine to separate the puree from the waste (peels, seeds, stalks, . . . ).  
       [0002] Industrial Patent N. 1288065 by the same Applicant discloses a method for enzymatic deactivation pertaining to the extraction of juices or purees from food products which provides for extracting the puree or juice at ambient temperature and then heating it in a recirculation loop at such a temperature as to obtain the enzymatic deactivation of the puree or of the juice, wherein said heating takes place at greater than ambient pressure. The plant comprises a straining machine which receives the whole or pre-treated and softened product and extracts juice or puree therefrom, to feed the recirculation loop in which the puree or juice circulates at such a temperature as to cause the enzymatic deactivation, a pump for feeding the puree or juice (which egresses from the straining machine at ambient temperature) in the recirculation circuit at greater than ambient pressure balanced by a counter-pressure device.  
       [0003] The recirculation circuit is maintained constantly full to prevent contacts of the puree or juice with air and for this reason no accumulation tanks or intermediate tanks for thermal breaks are provided.  
       [0004] However, in the straining machine the product may absorb air and hence during the time elapsing between the egress of the puree from the straining machine and its entry in the enzymatic deactivator (about 4-5 seconds) it may oxidise.  
       [0005] Therefore, to deaerate the puree it is sent to a traditional deaerator located after the deactivator, which works with a lower degree of vacuum than the vaporisation pressure of the product at the entry temperature.  
       DISCLOSURE OF THE INVENTION.  
       [0006] The aim of the present invention is to eliminate the aforesaid drawbacks and to make available a deaeration method and a deaerator of the puree in such a way as to assure the absence of absorbed air and thus prevent the puree itself from oxidising.  
       [0007] Said aims are fully achieved by the method and by the deaerator of the present invention, which are characterised by the content of the claims set out below, and in particular in that the method provides for the deaeration of the puree or of the juice in the intermediate phase of passage between the straining machine and the enzymatic deactivation plant, and not subsequently to the enzymatic inactivation, as was the case in the prior art.  
       [0008] The deaerator works with the maximum possible vacuum at an internal pressure whereto corresponds a vaporisation temperature of the product that is lower than the temperature of the incoming product.  
       [0009] To obtain the deaeration, the product enters at a temperature slightly exceeding the vaporisation temperature given by the vacuum in the deaerator. Since said degree of vacuum, with normal pumps and accessories available on the market, corresponds to product vaporisation temperatures exceeding ambient temperature, the need arises to heat the incoming product to make it exceed the vaporisation temperature threshold defined by the degree of vacuum of the tank. Said increase in the temperature of the product egressing from the straining machine is obtained in the following manner: a part of juice or puree egressing from the enzymatic deactivator at a temperature T 3  is brought back to re-enter the deaerator so that, mixing in a controlled manner into the flow with juice or puree at a temperature T 0 &lt;T 3 , it determines a temperature T 1  of the juice or puree entering the deaerator that is only slightly higher than the vaporisation temperature T 2  inside the deaerator, which depends on the pressure set inside the deaerator. 
     
    
    
     BEST MODE FOR CARRYING OUT THE INVENTION.  
     [0010] This and other characteristics shall become more readily apparent from the description that follows of a preferred embodiment illustrated, purely by way of non limiting example, in the accompanying drawing table, in which the sole FIGURE shows a front view of the device. 
    
    
     [0011] With reference to the FIGURE, the number  1  indicates a conduit for feeding puree or juice towards a deaerator  2  whose outlet  3  is directly connected to a pump  8  which extracts the product from the deaerator and feeds it to an enzymatic deactivator  4  (of the kind, for instance, described in the aforementioned IT 1288065) and to a recirculation loop described farther on.  
     [0012] The feeding conduit  1  receives the puree or juice from a straining or refining machine, not shown and of a known kind, or by a pump positioned downstream of the straining machine to evacuate the product therefrom.  
     [0013] Entry into the deaerator occurs on a plate  5  slightly convex upwards, i.e. towards the entry of the puree.  
     [0014] The reference number  6  indicates a known level measuring device, whilst the number  7  indicates a conduit connected to a vacuum pump for the extraction of air and vapour from the deaerator.  
     [0015] The puree egresses from the straining machine at a temperature T 0  corresponding to the ambient temperature of the space wherein the product to be processed is stored (normally about 10° C.) and it enters the deaerator at a velocity of about 3 m/s and therefore the passage from the straining machine to the enzymatic deactivator is particularly rapid and lasts only a few seconds.  
     [0016] The enzymatic deactivator  4  heats the product egressing from the deaerator to a certain temperature T 3  (normally between 85° C. and 95° C. and preferably about 95° C.). Part of said juice or puree is brought back to re-enter the deaerator in such a way that, mixing in a controlled manner in the flow with juice or puree at a temperature T 0 &lt;T 3 , it determines a temperature T 1  of the juice or puree actually entering the deaerator that is only slightly greater than the vaporisation temperature T 2  inside the deaerator, which depends on the pressure (or degree of vacuum) set inside the deaerator.  
     [0017] T 2  is substantially the temperature of the product after the “flash”, i.e. the working temperature of the deaerator.  
     [0018] In regard to the values of T 1 e T 2 , they are about 35-65° C. for T 1  and 30-60° C. for T 2 , which is normally lower than T 1  by just a few degrees.  
     [0019] To assure that the deaerator works in the best conditions, it is necessary to cause T 1 ≧T 2 ±5≧10° C.  
     [0020] The degree of vacuum in the deaerator is adjusted and a quantity of recirculation puree or juice is mixed that yields a temperature T 1  slightly higher than the corresponding set temperature T 2 .  
     [0021] The reference number  9  schematically indicates means for adjusting the flow rate of juice or puree at temperature T 3  that is mixed with that at temperature T 0 , constituted for instance by a device that measures the temperature T 1  at the inlet into the deaerator and transmits said value to a valve 10 at the outlet of the enzymatic deactivator in order to regulate the flow rate of the juice at temperature T 3 .