RU2576910C2 - Method for producing compote from gooseberry - Google Patents

Abstract

FIELD: food industry.

SUBSTANCE: invention relates to a canning industry, namely to a process for the production of canned banks 1-82-1000. Method includes preheating banks fruit with hot water at 85°C for 2-3 min to replace water syrup with a temperature of 95 °C. Banks roll covers self-exhaustion placed in a hot water bath temperature of 75 °C and subjected to heating for 15 minutes, raising the temperature of the bath to 100 °C. Next, sterilized jars without creating pressure in the unit when the water temperature reached 100 °C for 20 minutes, followed by cooling with cold water for 25 minutes.

EFFECT: invention contributes to the preservation of the natural components of resources used, reducing the amount of residual air in the bank prior to sealing and air removal during thermal processing, reduce the amount of boiled fruits and fruit with cracked skins can enhance the nutritional value of the final product, namely to keep the biologically active components of the feedstock, and vitamin C.

1 cl

Description

The invention relates to the canning industry and can be used in the production of gooseberry compote in cans 1-82-1000.

Sources that were searched by this method showed that the prototype of the proposed method is a method of sterilizing canned food "Gooseberry compote" in an autoclave [1] according to the mode

$$\frac{25-\mathrm{twenty}-25-25}{{\mathrm{one\; hundred}}^{\circ }C}\cdot 118\mathrm{to}P\mathrm{but}$$

where 25 is the duration of the period of heating water to 100 ° C, min;

20 - the length of the period of its own sterilization at 100 ° C, min;

25 - the duration of the cooling period, min;

100 ° С - sterilization temperature;

118 - back pressure in the autoclave, kPa.

The disadvantages of this method are:

- the need to create backpressure in the apparatus during the heat treatment, which requires additional energy consumption.

- the complexity of technological equipment for thermal sterilization, due to the fact that it operates under excessive pressure.

The technical result of the invention is aimed at creating a method for the production of compote, contributing to: reducing the duration of the process; preservation of biologically active components of the raw materials used; reducing the number of boiled fruits and fruits with cracked peels; saving heat energy, as well as reducing costs and increasing the competitiveness of finished products.

The specified technical result is achieved due to the fact that the fruits packaged in jars are filled with hot water at a temperature of 85 ° C for 2-3 minutes, then the water is replaced with syrup at a temperature of 95 ° C, then the jars are rolled up with self-extinguishing lids [2] and sterilized in open devices type without backpressure by mode

$$\frac{\mathrm{fifteen}-\mathrm{twenty}-25}{{\mathrm{one\; hundred}}^{\circ }C}\cdot 98\mathrm{to}P\mathrm{but}$$

where 15 is the duration of the period of heating water to 100 ° C, min;

20 - the length of the period of its own sterilization at 100 ° C, min;

25 - the duration of the cooling period, min;

100 ° С - sterilization temperature.

An example of the method

Before the syrup is poured for 2-3 minutes, pour hot water at a temperature of 85 ° C into jars with laid fruits, then replace the water with syrup at a temperature of 95 ° C, roll the jars with self-extinguishing lids, and place them in a bath (container) with hot water at a temperature of 75 ° C and subjected to heating for 15 min, increasing the temperature of the water in the bath (container) to 100 ° C. Then, for 20 minutes, the cans are sterilized at the achieved water temperature of 100 ° C, followed by cooling with cold water for 25 minutes, reducing the temperature of the water in the bath (tank) during this time to 40 C.

Pouring the syrup at a temperature of 95 ° C allows you to significantly save thermal energy due to the fact that the syrup is boiled at a temperature of 100 ° C and when canned according to the proposed method, the syrup is cooled to 95 ° C before pouring into cans, and not to 85 ° C. as provided in the technology manual.

The use of self-ejectable lids ensures the removal of air from the cans during their heating, which, firstly, provides the possibility of carrying out the sterilization process without creating back pressure in the apparatus and, secondly, the removal of air from the cans contributes to a more complete preservation of biologically active substances contained in the product because the lack of air in the banks significantly reduces their decomposition due to the cessation of oxidative reactions.

Salient features of the proposed method are: preheating fruits in jars before pouring syrup with hot water at a temperature of 85 ° C, which allows pouring syrup at a temperature of 95 ° C into a jar (according to current technological instructions, the temperature of the syrup when pouring 85 ° C) [1]; the cans are sealed with self-exhausting lids and the heat treatment is carried out without creating back pressure in the apparatus.

This mode provides energy savings due to the unnecessary creation of backpressure in the apparatus, it does not require sophisticated technological equipment for the implementation of heat sterilization of canned food, saving heat energy and improving the quality of finished products by reducing the duration of heat treatment.

Literature

1. A collection of technological instructions for the production of canned food. V.2, M .: Food industry. 1977.

2.Flaumenbaum B.L., Ibragimova L.R., Bloch G.A. Self-extinguishing glass packaging with type 1 closure with “breathable” lids. - Canning and vegetable drying industry, 1983, No. 1, p.29-32.

Claims (1)

A method for the production of gooseberry compote, characterized in that after filling the cans, the fruits are filled with hot water at a temperature of 85 ° C for 2-3 minutes, followed by replacing the water with syrup at a temperature of 95 ° C, then the cans are rolled up with self-exhausting lids and subjected to heat treatment without creating back pressure in open devices by mode: $$\frac{\mathrm{fifteen}-\mathrm{twenty}-25}{{\mathrm{one\; hundred}}^{\circ }C}.$$