UA114050C2 - INFRARED RADIATOR - Google Patents

Abstract

The invention relates to heat exchanger technology, namely electric heaters that convert electrical energy into thermal energy and can be used for autonomous heating of domestic and industrial premises as a local heating device, in particular a radiator. The objective of the present invention is to improve the infrared radiator by using such a set of structural elements and materials from which they are made, resulting in maximum heat output in combination with high consumer properties and a high level of energy conservation. The infrared radiator consists of a hollow frame made of high-conductive metals or their alloys, and is a set of sections with channels, the channels are intended for circulation in them coolant and have the form of a cut cone, facing a larger base to the through pipe of the upper part of the frame, which connects these channels, and the smaller base of the cone channels facing the lower tube and united by it, while the lower tube has a casing of high-temperature material placed in it infrared heating linen element, made of carbon thread, woven in the form of a "pigtail" and placed with the possibility of connection to a voltage source, said housing is made tubular and pre-created in it, and the space between the housing and the inner surface of the lower pipe, is filled with heat. a low-boiling liquid, in the through pipe of the upper part of the frame there is a valve for pumping air from the channels and subsequent supply of coolant.

Description

The invention belongs to heat exchange equipment, namely to electronic heating devices that convert electrical energy into thermal energy, and can be used for autonomous heating of domestic and industrial premises as a local heating device, in particular a radiator.

At this time, radiators, which are convective-radiative heating devices consisting of separate, usually columnar elements (sections) with channels, inside which the coolant circulates, are widely used for air heating in domestic and industrial premises. Heat from the radiator is removed by radiation, convention and thermal conduction. Radiators can be cast iron, aluminum, steel and bimetallic.

Each of them has certain advantages that depend, first of all, on the thermal conductivity of the material from which they are made, and their power and durability. All of them are intended for central heating systems and cannot be used in autonomous mode, which is very relevant today.

Another type of radiators are oil radiators. They are a hermetic case filled with mineral oil, in which an electric heater is placed. The heat from the electric heater is transferred to the oil, then to the body, the temperature of which does not exceed 60-70 "C, and from it to the surrounding air. Radiators of this type are designed for autonomous use, but they have a number of disadvantages, among which there is a fire hazard, the cause of which is failure thermostat.

A common disadvantage of known radiators is significant energy consumption and their high cost.

The heaters of the new generation are infrared radiators. The advantages of infrared radiators are due to the principle of heat transfer. Infrared heaters use two types of heat transfer: long-wave infrared and convection.

Such a combination of types of heat transfer provides an opportunity for efficient use of electricity, which significantly increases the performance of heaters and, accordingly, reduces their cost.

Modern technical developments of infrared radiators are based on the optimal combination of design features of the heating element and the design of the radiator itself.

A known electric radiant heating device, consisting of a body, in

From which there is a heat-radiating panel (patent RF Mo 2168115, MPK R240 13/00, publ. 27.05.2001, bull. Me15) with tubular electric heaters fixed on it, which during operation transfer heat through the holder to the heat-radiating aluminum panel.

The lower surface of the panel facing the floor is heated to a temperature of 200 "С, emitting radiant energy in the form of infrared radiation. This heater is also equipped with heat-insulating and reflective elements located above the heat-emitting panel.

A significant disadvantage of the heater is that the source of heat radiation is an aluminum panel, which is heated by a tubular heating element, but it does not ensure uniform heating of the panel and does not fully transfer thermal energy to the heat-emitting surface, as a result of which the efficiency of the heater does not exceed 70 95. Inertia of heating panel also increases losses and reduces efficiency.

It should be noted that such electronic heating devices have a rather narrow range of applications. Such devices are characterized by low power and insufficient consumer characteristics.

A well-known electronic heating device (infrared radiator, RF patent Mo 2304367

NOBV 3/34, publ. 10.08.2009) contains two layers of an electrical insulating base, between which is placed an electrically conductive resistive layer made on the basis of carbon fibers, and electrically connected to it current leads, made in the form of a flexible current lead chain made of soft wire. The electrically conductive resistive layer is made in the form of zigzag sections of a resistive chain made of carbon fibers. The ends of each section of the resistive circuit are metallized with copper and wound on a current lead, and all sections of the resistive circuit are made of continuous unidirectional carbon fibers consisting of elementary fibers treated with a special compound.

But the disadvantage of this device due to the presence of contact of carbon fibers with the surface of the electrical insulating base is insufficiently efficient heating and a short service life of the carbon fiber.

Convection heating panel is also known (patent of Ukraine Mo 47962, NOBV 3/00, publ. 25.02.2010). It contains front and rear heat-radiating elements, between which there is an element in the form of a carbon thread. The heating element is made with 60 possibilities of connection to the electrical network.

But the disadvantage of this heating device is the relatively low efficiency of using the heating element, which is caused by a decrease in its temperature due to the presence of a significant contact area with heat-radiating elements.

A heating device is known (RF Mo 2455579, MPK E24N 1/10, publ. 10.07.2012) for obtaining thermal energy from electrical energy containing at least one resistive electric heating element connected to a power source, heat-accumulating substance - ceramic material. The heating element is made of a ceramic pipe with a protective layer, which contains a carbon thread with a protective coating and zero water absorption of a monolithic ceramic cylinder with holes to increase the heat exchange surface and a channel for laying the heating element. The disadvantage of this device is a long initial heating period (68-75 minutes) and manufacturing technology is also more complex compared to standard radiators.

The closest in technical essence to the claimed invention is a useful OA model

Me103052 (Е24Н 7/06, НО5 В3/00, publ. 25.11.2015, bull. Mo 20).

The known solution belongs to the infrared heating device and contains two heat-radiating panels, which are interconnected to form at least one channel. An infrared heating element is placed in the channel in the form of carbon threads, which are folded into a cord by braiding type "pigtail", the specified element is connected to a voltage source.

The junctions of the channel or channels and the cord made of carbon filaments are additionally treated with a suitable substance, for example carbon black, to enhance infrared radiation. In addition, a vacuum is created in the channel in which the heating element is placed.

The well-known heating device uses modern approaches to ensure energy saving, safety, reliability and other consumer indicators.

But the scope of use of the claimed device is limited, in particular, by its form in the form of interconnected panels. In addition, additional structural elements that enhance heat transfer without losing the energy used are not provided.

The task of the present invention is to improve the infrared heating device (radiator) by using such a combination of structural elements and materials from which they are made, as a result of which maximum heat transfer is achieved in combination with

With high consumption properties and a high level of energy saving.

The task is solved by the fact that the infrared radiator, according to the invention, consists of a hollow frame made of highly heat-conducting metals or their alloys, and is a set of sections with channels, and the channels are designed for the circulation of the coolant in them and have the form of a truncated cone, turned larger the base to the through pipe of the upper part of the frame, which unites the indicated channels, and the smaller base of the cone, the channels face the lower pipe and are connected by it, while the lower pipe has a casing made of high-temperature material with an infrared heating element made of of carbon filament woven in the form of a "pigtail" and placed with the possibility of connection to a voltage source, the specified infrared heating element is installed in a tubular casing made of high-temperature material with a pre-created vacuum in it, and the space between the casing and the inner surface of the lower tube filled with a heat carrier that represents is a low-boiling liquid, a valve is installed in the through pipe of the upper part of the frame for pumping air from the channels and the subsequent supply of the coolant.

The set of design features of the claimed heating device (radiator) belongs both to the heating element and to the body of the device, as well as to the materials from which they are made, allowing to achieve a technical result, namely, high heat transfer and saving of electrical energy at the level other consumer properties.

At the heart of the invention are processes that are formed by the action of the infrared component of heat transfer, which is provided by a suitable heating element connected to a power source.

The infrared heating element operating in the proposed radiator is made of carbon thread woven into a "braid", which allows to significantly strengthen the infrared radiation and thereby make an additional contribution to the heat transfer received.

The heat flow emitted by the infrared heating element is characterized by a wavelength of 8-15 μm.

Placing the infrared heating element in a vacuum helps to create such conditions in which there are no heat losses of the radiating element, as it happens in an air environment.

Placing the infrared heating element in a tubular casing made of a high-temperature material, that is, one that does not break down under the influence of thermal radiation, contributes to the uniform distribution of thermal energy in the coolant.

The high-temperature material from which the casing is made can be, for example, special glass or ceramics.

The heat carrier in this technical solution is a low-boiling liquid (35-45 C), this requirement is due to the maximum absorption of infrared radiation, on the one hand, and, on the other hand, its special property of increasing heat transfer to the surface of the radiator body. One of the possible liquids is, for example, freon or bromolithium liquid.

In cases where the liquid used for the heat carrier does not contain water, it should be added in small quantities, which will help to exclude the formation of excess pressure, and therefore, the condensation of the heat carrier will occur evenly and efficiently. As the infrared radiation acts on the liquid, the coolant begins to evaporate, forming a gas-liquid environment inside the channels of the body, while conditions are created for breaking the intermolecular bonds of the substances of the liquid used.

This process leads to a several-fold increase in particles that transfer additional thermal energy to the internal surfaces of the radiator. Having reached the upper part of the radiator, the gas-liquid medium passes into the liquid phase and returns to the initial state, the number of such cycles ranges from 45 to 60 per minute.

Another feature of the claimed device is the execution of a channel for the circulation of the heat carrier liquid in the form of a truncated cone, the smaller base of which faces the pipe in which the heating element is placed. As a result of the use of such a form and placement of the channels, when the gas-liquid medium enters them, an increased pressure is created, which, in turn, activates the heat exchange processes.

As for the material from which the body of the radiator is made and on which the heat transfer to the air also depends, it must have high thermal conductivity. Among all possible variants of the specified material, aluminum and its alloy and iron and its alloys should be singled out.

In addition, the inner surface of the lower pipe is covered with a layer of soot, which has an absorption coefficient of IR radiation close to 1, which ensures maximum intensity and uniformity of its heating.

The design of the radiator proposed by the author involves equipping the equipment with automation that meets high technical requirements. For additional heat removal, the infrared radiator can be equipped with overlays.

The essence of the claimed technical solution is explained by the following drawings, where fig. 1 - schematic diagram of the radiator, fig. 2 - diagram of the radiator in section: 1 - hollow frame, 2 - channels,

C - coolant, 4 - hollow pipe, 5 - lower pipe, 6 - heating element, 7 - voltage source, 8 - valve, 9 - plug.

The claimed radiator works as follows: the device is connected through an infrared heating element to a 220 V voltage source. The heating element is used to heat a special liquid, which forms a vapor-liquid mixture when heated. The resulting steam condenses and gives off heat through the walls of the radiator body to the surrounding environment. The vapor-liquid cycle is repeated many times.

The infrared heating element at a voltage of 220 V consumes 280 W/h. The working electric current is 1.1 A. The radiator weighs 10.1 kg, and the overall dimensions are 735x540x48 mm. The operating temperature on the surface of the radiator is 55 "С. The thermal power at the specified parameters is an average of 1,000 W.

Such a radiator is designed for heating a room with an area of 10-12 m at a height of 2.5 m.

Warming up to optimal parameters takes place within 10 minutes.

Thus, the special design of the claimed radiator ensures the achievement of a technical result. When compared with the known level of technology, this is the cheapest device in the world in terms of operating costs: on average, 200 W of electrical energy is spent to generate 1 kW of thermal energy.

The claimed space heating device works autonomously - does not produce harmful radiation, is reliable and safe during operation. (510)

Claims (5)

FORMULA OF THE INVENTION 1. An infrared radiator, which is distinguished by the fact that it consists of a hollow frame made of highly heat-conducting metals or their alloys, and is a set of sections with channels, and the channels are designed for the circulation of the heat carrier in them and have the form of a truncated cone, with the larger base facing the through the pipe of the upper part of the frame, which unites the specified channels, and the smaller base of the cone faces the lower pipe and is connected by it, while the lower pipe has a jacket made of high-temperature material with an infrared heating element made of carbon thread placed in it, braided in the form of a "braid", and placed with the possibility of connecting to a voltage source, while the jacket is made tubular, and a vacuum is previously created in it, and the space between the jacket and the inner surface of the lower pipe is filled with a coolant, which is a low-boiling liquid, in a through pipe a valve for pumping air from the channel is installed on the upper part of the frame iv and subsequent coolant supply. 2. An infrared radiator according to claim 1, which is distinguished by the fact that it is additionally equipped with pads for additional heat removal. 3. An infrared radiator according to claim 1 or 2, which is characterized by the fact that the frame is made of aluminum or its alloys. 4. An infrared radiator according to claim 1 or 2, which is characterized by the fact that the frame is made of iron or its alloys. 5. An infrared radiator according to claim 1 or 2, or 3, or 4, which is characterized by the fact that the inner surface of the lower pipe is covered with soot. in the first year of the year s s y a r a ge kre v » still Z SHUI J still m V Ya ki y ke en nen ev y kir shshi she s, claim 2 Y OO M Z: I Pk identity y Kak y. i U B o ZHE ne Ky i pa BK Ty: shchi "i pi Esh 5 iV5B Ek nih kyi "o zhe ze oz, EE i oon o shen R ; her I Zov chn. 1 Fi.y