RU2444683C2 - Refrigerating device - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: refrigerating device for continuous cooling of liquids comprises a line of liquid supply, which is connected to a system of liquid supply, an accumulating reservoir for ice, a grinding device, a mixing and dosing unit, and also a sampling point. The ice after its grinding in the grinding device may be mixed in the mixing and dosing block with the liquid arriving from the supply line, and the liquid mixed with the ice may be sampled in the sampling point.

EFFECT: device makes it possible to perform very fast continuous cooling of liquids, saving power and area, and provides for their hygienic quality.

10 cl, 1 dwg

Description

Technical field

The invention relates to a refrigeration device for continuous cooling of liquids by a flowing method.

State of the art

The prior art devices for cooling liquids. In the prior art, water is maintained chilled in insulated tanks using Peltier elements or refrigeration compressors, or is cooled by a flow method in high-performance units. For example, DE 1960 975 describes a liquid refrigeration device in which a liquid is cooled by a compressor. DE 195 17 638 A1 describes a method for manufacturing a chilled finished drink, as well as an automatic machine for preparing chilled finished drinks, in which crushed ice is added to a hot product in which the powder components dissolve. Known from the prior art devices for cooling liquids have several disadvantages. So the devices, due to the presence of an integrated water tank, require significant space. If a reservoir of water is stored in the tank, there is a risk of microorganisms, bacteria or biofilms forming in the stored water. In addition, the content of the stock of cold water, as a rule, is associated with high energy consumption. Finally, the capacity of such devices is limited; if the supply of chilled fluid is used up, you need to wait again for a while until the new refilled fluid reaches the required temperature again. The next disadvantage arises if high-performance units are used for cooling by flow method, since the required amount of energy, expressed in kilowatts, cannot be provided in ordinary apartments and kitchens.

Disclosure of invention

Based on this, the object of the present invention is to provide a liquid refrigeration device that requires little space, which operates in an energy-saving mode and provides liquids of high biological or microbiological quality.

This problem is solved using the characteristics of paragraph 1 of the claims. Useful options for the development of the invention, which can be used separately or in combination with each other, are the subject of the dependent clauses.

A device for continuous cooling of liquids according to the invention, consisting of a liquid supply line connected to a liquid supply system, an ice storage tank, a grinding device, a mixing and dosing unit, as well as a selection point, is characterized in that the ice after it is crushed in a grinding device can mix in the mixing and dosing unit with the liquid, and ice-filled liquid can be taken at the sampling point. Due to this, in contrast to the existing level of technology, a significant improvement is achieved in terms of microbiological quality, cooling power, as well as the space occupied by the device. Cold ice is ground finely, crushed in rolls or distributed by nozzles, and then fed into the liquid. The starting point is ice with a very low temperature, for example, -20 ° C and below. This ice is prepared so that it can be quickly and easily mixed with the liquid to be cooled. It is important that the ice in a very fine-grained form is uniformly mixed into the liquid to be cooled. In this case, small particles of ice melt, and the mixing temperature is quickly established. Thanks to the refrigeration device according to the invention, it is no longer necessary to maintain a supply of chilled liquid. Moreover, the liquid is supplied to the refrigeration device through the liquid supply line. When an appropriate amount of finely chopped ice is supplied to the liquid, for example, water, which is supplied at room temperature via the liquid supply line, can be cooled to a temperature close to freezing in a few seconds. Due to the fact that it is not necessary to maintain a supply of chilled water, there is no risk of microorganisms, bacteria or biofilms in stored water in the refrigeration unit.

It turned out to be useful if the refrigeration device has a first filtering device between the liquid supply line and the mixing and dosing unit and / or between the mixing and dosing unit and the sampling point a second filtering device. Using these filtering devices, it is ensured that the supplied liquid is free of contaminants and, in addition, the liquid that leaves the refrigeration unit at the sampling point does not contain ice particles. In turn, due to the fact that the ice particles are retained, improved cooling of the flowing liquid is achieved, and thus, energy consumption is reduced. In addition, it turned out to be useful if ice granules or ice cubes are fed directly into the water supply line along the second path. There is no need for a separate dosing of ice.

In a preferred embodiment, the refrigeration device has a device for determining the temperature of the liquid. It is also an advantage if the refrigeration device has an indication unit on which the user can check the current temperature of the liquid.

An advantage is also if the temperature measuring device is located between the mixing and dosing unit and the sampling point. This is an advantage because it is important for the user to know what temperature the liquid has at the point of sampling. Since the temperature of the fluid flowing through the supply line is controlled by using mixed ice, it is important for the user to find out what temperature the fluid has after the mixing process in order to have an idea of what temperature the fluid being taken has.

In addition, it is advantageous if the refrigeration device has a unit for inputting the required temperature of the liquid.

It also turned out to be useful if the refrigeration unit has a measurement and control unit. Using this unit, you can determine the current temperature of the liquid, compare it with the required set temperature and change the temperature accordingly by regulating the ice flow.

In a particularly preferred embodiment, the refrigeration device compares the required temperature with the current temperature of the liquid using the measuring and control unit, from this determines the amount of ice per volume required to achieve the desired temperature, and using the measuring and control unit it mixes this amount of ice with the liquid. The liquid temperature in the following preferred embodiment can also be repeatedly measured between the liquid supply line and the sampling point in order to set the target temperature using a control and adjustment circuit.

It has also proved useful if the refrigeration unit is part of the refrigeration unit. It may be a refrigerator, chest freezer or a combination device.

An advantage is also if the refrigeration unit has at least one UV lamp. A UV lamp provides additional protection by which possible biological or microbiological residual risk can be avoided. This UV lamp should preferably be near or directly at the sampling point, and if necessary, contain a sampling point free of microorganisms.

In addition, it is advantageous if the refrigeration device further has a device for making and preparing ice cubes.

The refrigeration device according to the invention allows very fast continuous cooling of liquids, saving energy and saving space, and ensures their hygienic quality.

Brief Description of the Drawings

Other advantages of the embodiments of this invention are explained in the text below on the basis of an example implementation, which, however, the present invention is not limited to, and also with reference to the accompanying drawing.

It schematically shows:

Figure 1: Schematic representation of a refrigeration device, front view.

The implementation of the invention

In the following description of preferred embodiments of the present invention, the same reference numbers indicate the same or comparable components.

Figure 1 in a schematic projection of a front view shows a refrigeration device for cooling liquids. The liquid to be cooled flows through the liquid supply line 2 to the filter device 3. This filter device 3 can use various filtering technologies, for example, an anion exchange resin or a cation exchange filter, an activated carbon filter, an ultrafiltration unit, a microfiltration unit or a reverse osmosis unit. After filtration, the liquid enters the mixing and dosing unit 7. Here, the liquid is mixed with the accumulated refrigeration device 5 in the storage tank 4 with ice, which is crushed using a grinding device 6. The storage tank 4 has a means 5 for cooling. In addition, the device has a block 11 for entering the desired temperature of the liquid. A device for measuring and controlling (not shown) determines from the ratio of the actual and set temperature the required amount of ice supplied and, thus, regulates the temperature of the liquid by changing the liquid supply or ice supply. Moreover, using the device 10 for determining the temperature, the current temperature of the liquid between the dosing unit and the selection point 8 is determined. In figure 1, the device has a second filtering device 9, which prevents the penetration of small particles of ice through the point 8 of the selection in the selected fluid. Depending on the temperature of the ice and the dosed amount, as well as the temperature of the liquid to be cooled, it is possible to purposefully adjust and change the mixing temperature. So, for example, from 1 liter of water having a temperature of 15 ° C, 400 grams of ice having a temperature of -20 ° C, you can get more than 1 liter of water with a temperature of approx. 5 ° C.

The refrigeration device according to the invention allows very fast continuous cooling of liquids, saving energy and saving space, and ensures their hygienic quality.

List of symbols in the drawing

(1) Device

(2) Fluid supply line

(3) Filter device

(4) Storage capacity

(5) Means for cooling the storage tank

(6) Means for grinding

(7) Mixing and dosing unit

(8) sampling point

(9) Second filtering device

(10) Device for determining the temperature

(11) Block for entering the desired desired fluid temperature

Claims (10)

1. A refrigeration device (1) for continuous cooling of liquids, comprising a liquid supply line (2) connected to a liquid supply system, an ice storage tank (4), a grinding device (6), a mixing and dosing unit (7), and a selection point (8), characterized in that in the mixing and dosing unit (7), it is possible to mix ice crushed in a grinding device (6) with liquid supplied from the supply line (2) and it is possible to take liquid mixed with ice, at the point (8) of selection, at than the refrigeration device (1) between the liquid supply line (2) and the mixing and dosing unit (7) is equipped with a first filtering device (3) and / or between the mixing and dosing unit (7) and the selection point (8) by the second filtering device (9 ) 2. The refrigeration device (1) according to claim 1, characterized in that the refrigeration device (1) is equipped with a device (10) for determining the temperature of the liquid. 3. The refrigeration device (1) according to claim 2, characterized in that the temperature measuring device (10) is located between the mixing and dosing unit (7) and the selection point (8). 4. The refrigeration device (1) according to claim 1, characterized in that the refrigeration device (1) is equipped with means (5) for cooling the storage tank (4). 5. The refrigeration device (1) according to claim 1, characterized in that the refrigeration device (1) is equipped with a unit (11) for entering the desired temperature of the liquid. 6. The refrigeration device (1) according to claim 5, characterized in that the refrigeration device (1) is equipped with a measurement and control unit. 7. The refrigeration device (1) according to claim 6, characterized in that it is possible to compare the refrigeration device (1) with a predetermined liquid temperature using the measurement and control unit with the actual liquid temperature, determine from this the quantity of ice necessary to achieve the required temperature, and mixing it in the mixing and dosing unit (7) using the measuring and control unit. 8. The refrigeration device (1) according to claim 1, characterized in that the refrigeration device (1) is made as part of the refrigeration apparatus. 9. The refrigeration device (1) according to claim 1, characterized in that the refrigeration device (1) is equipped with at least one UV lamp. 10. The refrigeration device according to claim 1, characterized in that the refrigeration device is additionally equipped with a device for the manufacture and preparation of ice cubes.

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