WO2020256587A1

WO2020256587A1 - Method for protecting a heat exchanger of refrigerating and ventilating plants from freezing

Info

Publication number: WO2020256587A1
Application number: PCT/RU2020/000259
Authority: WO
Inventors: Кирилл Павлович ОРЛОВ
Original assignee: Кирилл Павлович ОРЛОВ; ОРЛОВА, Валерия Александровна
Priority date: 2019-06-19
Filing date: 2020-05-26
Publication date: 2020-12-24
Also published as: FI20205580A1; RU2724661C1; FI129069B

Abstract

The present invention relates to means for removing condensate from heat-exchange apparatuses, more specifically from refrigerating and ventilating plants, from conditioners, heat pumps and recuperators. The technical problem, the solution to which is provided with the use of the claimed invention, is the absence, in a range of technical means and methods for protecting heat pumps and refrigerating and ventilating plants, of methods making it possible to prevent heat exchangers from freezing, without incurring substantial energy costs. The technical result of the claimed invention is the possibility of preventing icing of heat exchangers while achieving a reduction in the energy costs for providing this process. The technical result is achieved in that, when the claimed method is implemented, icing is prevented by creating mechanical oscillations, more specifically by high-frequency oscillations being supplied to the heat exchanger and, as a result of the action of said oscillations, a build-up of ice loses the capability of persisting on the surface of heat-dissipating elements.

Description

METHOD OF PROTECTION AGAINST FROSTBITE HEAT EXCHANGER OF REFRIGERATION AND VENTILATION UNITS

DESCRIPTION

Technology area

The present invention relates to means for removing condensate from heat exchangers, namely from refrigeration, ventilation units, air conditioners, heat pumps, recuperators.

Prior art

During the operation of refrigeration, ventilation units, air conditioners, heat pumps, recuperators, the air passing through the heat exchangers is cooled, moisture vapor condenses on cooled surfaces and heat transfer parts, turning into ice crystals. At present, such methods of combating the formation of ice are known, such as additional heating of the air, the transition of installations from the cooling mode to the defrosting mode, and air preparation by the method of drying it. All existing technologies are aimed at preventing the formation of ice and, therefore, require significant energy consumption to maintain trouble-free operation of the heat exchanger. Their efficiency decreases in proportion to the decrease in outdoor temperature and humidity.

From the existing state of the art is known "A method for removing condensate from a water collector of a heat exchanger-condenser with a hydrophilic material and a device for its implementation" (patent Ns 2183799, application. 08/20/2000, publ. 06/20/2012, patent holder: Open Joint Stock Company “Rocket and Space Corporation "Energy" named after SP Korolev ")

The invention relates to space technology, specifically to methods for removing condensate from heat exchangers-condensers of air conditioning systems inhabited compartments of spacecraft for various purposes. In addition, the invention can be used in ground air conditioning systems serving premises that are particularly sensitive to dripping moisture. The disadvantage of this technical solution is the complexity of its implementation and focus on the use in zero gravity.

Also known from the prior art is the "Condensate drain" (Patent N ° 75018, application. 02/20/2008, publ. 07/20/2008).

The utility model relates to the field of heat and power engineering, more specifically, to condensate traps, which are part of heat exchange devices in which water vapor is used as a heat carrier. The specified technical solution is a condensate drain, including a condensate trap connected to the pipes of the heat exchanger and a device for removing condensate from the condensate trap, characterized in that the condensate drain is equipped with a pipe or a branch pipe for draining condensate from the condensate trap, while the inlet of the pipe or branch pipe is located at a level that provides in the process of removing condensate, it is immersed in a liquid, mainly condensate, while the junction of the condensate collector and the pipes of the heat exchanger is located in the upper part of the condensate collector above the surface of the accumulated condensate.

The disadvantage of this technical solution is its focus on the removal of condensate at a positive air temperature, therefore, the failure to perform the function of removing condensate when the temperature drops.

To prevent the formation of condensation, heating elements insulated with foam material are also used, installed on at least one side wall and / or on the door frame of the device. The disadvantage of heating elements, such as electric heaters, is the relatively high consumption energy. It is known to use heating elements in the form of pipelines insulated with foam material through which compressed refrigerant flows. The compressed refrigerant generates excess heat generated in the refrigerant circuit of the device, which heats up the associated surface and prevents unwanted condensation.

The disadvantage of such heating elements is that the refrigerant piping is expensive and difficult to manufacture. On the outer surface, for example, areas of increased pressure sensitivity may occur. Additional disadvantages are the relatively high energy consumption, and, therefore, high energy consumption, the possibility of local overheating, as well as, under certain circumstances, the effect on the temperature inside the device.

Thus, all currently existing technical solutions in this area are aimed at heating heat exchangers that are part of refrigeration and ventilation units.

Disclosure of the essence of a technical solution

The claimed invention is carried out in order to solve the above problem, and, therefore, the technical problem of the present invention is to expand the arsenal of technical means to protect refrigeration and ventilation units from frostbite without significant energy consumption.

The technical result of the claimed invention is to provide the ability to prevent icing of heat exchangers when the condition for reducing the cost of electricity to ensure the specified process is achieved.

The technical result is achieved by the fact that when implementing the proposed method, icing is prevented by creating mechanical vibrations, namely, due to the fact that the heat exchanger is supplied high-frequency vibrations and, as a result of their effect, ice loses its ability to be retained on the surface of the heat sink elements.

To ensure the removal of ice in this way, the following elements are required: a frequency generator, a frequency emitter, a microcontroller, temperature and humidity sensors.

These elements are interconnected in such a way that sensors and a frequency generator are connected to the microcontroller, and frequency emitters are connected to the frequency generator. The radiated frequencies are in turn mounted on heat exchangers. The listed elements are connected to each other using electrical wires, in turn, the frequency emitters can be attached to the radiator using adhesives, welding, or can be made as a structural part of the radiator.

To achieve the specified technical result, the temperature and humidity sensors take readings of the air condition and send them to the microcontroller, which, in turn, gives a command to the frequency generator to generate the operating frequency and impact force for the frequency transmitter. The frequency emitter converts an electrical signal into mechanical vibration, as a result of which the formed layer of ice is destroyed.

The transformation of an electrical signal into mechanical vibration, namely, the receipt of vibration (inverse piezoelectric effect) is associated with the impact on the frequency transmitter-piezoelectric crystal of electric voltage. As a result of this effect, the faces of the piezoelectric crystal are displaced. When an alternating high frequency voltage is applied to the piezoelectric crystal, the piezoelectric crystal begins to contract and expand with a high frequency, a high-frequency pressure change occurs around it, which leads to the occurrence of directional vibrations, that is, the vibration necessary to achieve the claimed technical result. During the operation of the frequency emitter, due to the difference in the density of the heat exchanger material and ice crystals, the ice crystals are detached (torn away) from the heat transfer surfaces of the heat exchanger.

Embodiments

Depending on the materials used for the manufacture of heat exchangers, as well as its design and shape, the emitter of frequency vibrations and the relative position of the elements are selected. Control equipment is selected in each specific case, depending on the selected emitter of frequency vibrations.

Within the framework of the proposed method, the following types of emitters of frequency vibrations can be used: electromagnetic, electrodynamic (coil, tape, isodynamic, orthodynamic, Hale), electrostatic (capacitor, electret), piezoelectric (piezoceramic, bimorphic).

In addition to the above types and types of emitters, others, less traditional, can be used. The choice of a radiator depends on its power and efficiency, as well as the elements transmitting vibration.

Depending on how the vibration emitter is located, contact or non-contact, heat exchanger materials are selected, which should have two main properties: high thermal conductivity and good vibration conductivity, such are many metals and alloys. After choosing the material, the shape of the radiator is selected in such a way that the vibration spreads evenly over the entire heat transfer surface. In the case of structural and structural impossibility of installing vibration emitters on the surface of the heat exchanger, contactless emitters are selected.

Claims

METHOD OF PROTECTION AGAINST FROSTBITE HEAT EXCHANGER OF REFRIGERATION AND VENTILATION UNITS FORMULA OF THE INVENTION 1. Method of protection against frostbite of a heat exchanger used in a refrigeration and ventilation unit, characterized in that it includes taking readings of the air condition by temperature and humidity sensors, transmitting commands to the microcontroller to the microcontroller a frequency generator to generate an operating frequency and impact force for a frequency emitter, conversion of an electrical signal into mechanical vibration by the emitter.