RU2108689C1 - Electric convector - Google Patents

Abstract

FIELD: heating of air in rooms in cold season by convective transfer of heat. SUBSTANCE: electric convector has body of box-shaped form with inlet and outlet holes, support 1 of electric insulation material coupled to supports of heating elements 3 with electric insulation backing coated on one side with resistive material. Heating elements 3 ha ratio of height H to width B satisfying inequality 1.8 < H/B <2.3, ratio of spacing t of heating elements to width B meeting inequality 1/4 < t/B < 1/6 and are installed with relative spacing t/H determined by inequality 1/11 < t/H < 1/7. Upper and lower walls of body 2 are manufactured in the form of panels arranged in parallel one another. Each panel has holes in the form of three-row isometric slits with relation of distance l_r between two rows to diameter d of slit amounting to l_r=0.8-1.4, relation of length 1 of slit to diameter d amounting to 1/d=6.0-8.0 and relation of interaxis distance x of two adjacent slits to diameter d of slit amounting to x/d=1.9-2.6. EFFECT: improved functional efficiency and reliability of convector. 6 dwg

Description

 The invention relates to an electric heating technique used to create thermal comfort in rooms in the cold season, in particular to electric convectors, and is intended for heating air in rooms by convective heat transfer.

 Known electroconvectors containing a housing with openings for air inlet and outlet, between which inside the housing on supports of electrical insulation material a heater is installed, made in the form of a spiral and connected through a switch to the power supply [1].

The disadvantage of such electroconvectors is that the heater, made in the form of a spiral of high-resistance material, is heated to a high temperature, reaching 450-500 ^o C and more [1], and this leads to thermal decomposition of dust and moisture with the release of harmful impurities into the atmosphere of the heated premises. At the same time, the required comfortable conditions in the room are not provided, because the air quality is deteriorating (it becomes drier, less environmentally friendly, with low relative humidity).

 For the microclimate, the air should be sufficiently heated, moderately humid and clean.

 In addition, well-known electroconvectors have low reliability. When the spiral burns out, the electroconvector loses its working ability, and the ends of a hot dangling spiral under certain conditions can lead to a fire.

 The closest in technical essence and the achieved effect is an electroconvector [2], containing a box-shaped case with inlet and outlet openings, between which inside the body on supports made of insulating material there is a heater connected through a switch to the mains. The heater of this electroconvector is made in the form of a set of separate heating elements, each of which contains a rectangular electrically insulated substrate. On one of the planes of the substrate, contact bars placed along its short opposite sides are coated with resistive material covering the entire surface of the plane of the substrate between the tires. In this case, the individual elements of the set are mechanically interconnected in series and oriented by their planes parallel to each other, and electrically connected via contact buses into groups with parallel connection of elements in groups, and the groups are connected to the power supply via a switch with the possibility of series, parallel or series - parallel connection between each other.

 This electroconvector is taken as a prototype.

 The difficulty in creating a highly efficient and reliable electroconvector lies in the fact that the designer has to simultaneously take into account the requirements of a number of scientific disciplines, such as electrical engineering, heat transfer, electromagnetic wave theory, radiation heat transfer theory, reliability theory, mechanics, aerodynamics, pneumatics, hydraulics and others.

 Taking into account the requirements and patterns, for example, aerodynamics, pneumatics and hydraulics, allows rationally (optimally) designing the flow parts of the electroconvector (inlet, outlet, flow channels formed between the heating elements, air flow of the structural elements, etc.), as well as evaluate the effect of flow parts on the effectiveness of his work.

 Indeed, as shown by theoretical and experimental and theoretical studies, the efficiency and reliability of the electroconvector depend critically on how rationally the structural dimensions are selected and with what optimal pitch the heating elements forming the flow channels of the electroconvector are located relative to each other, i.e. air flow path in it.

 With a small step, the number of heating elements increases, which leads to an increase in their mutual irradiation and an increase in the material consumption, mass and cost of the electric convector.

 In addition, with a small step, the total hydraulic losses in the flow channels of the electroconvector, through which air moves, sharply increase. As a result, the air flow through the convector decreases and the chimney effect is weakened, i.e. natural draft decreases [1], pp. 100-103; 118).

 With a small step, an increase in the number of heating elements, equivalent to their reservation, leads to an increase in reliability [3], since failure of at least one heater due to mutual irradiation of neighboring heaters does not lead to a complete failure of the electric convector. However, in this case, as a result of increased hydraulic losses in the flow channels, the efficiency of the electroconvector as a whole decreases, since the heating of the room air to the optimum (comfortable) value takes a long time, which creates some inconvenience to the consumer.

 With a large step, the number of heating elements, their mutual irradiation, the total hydraulic losses in the flow channels and the material consumption of the electroconvector will be the minimum possible, and the air flow through the electroconvector and its natural draft will be maximum.

 With the optimal step of the heating elements and the optimal size ratios of the flow channels, inlet and outlet openings, the performance of the electric convector will be the best, i.e. optimal.

 The objective of the invention is to increase the efficiency and reliability of the electroconvector.

The stated technical problem is solved in that in the known electroconvector comprising a box-shaped body with inlet and outlet openings, supports made of electrical insulation material, connected to the supports are parallel-mounted heating elements with an electrically insulated substrate coated on one side with resistive material, united by groups of contact bars in groups and connected through the switch to the mains, the heating elements are made with the ratio of the height H to the width B of the heating element in the opt minimum values of H / B defined by the inequality 1.8 <H / B <2.2, the ratio of the step of the heating elements t to the width B of the heating element in the optimal range satisfying the inequality 1/4 <t / B <1/6, and established with a relative step t / H in the region of optimal values limited by the inequality 1/11 <t / H <1/7, while the upper and lower walls of the casing are made in the form of panels arranged parallel to each other, on each of which holes are made in the form three-row slits of equal size, the distance between the two rows _r l, reacted Noe to diameter d slots, _p is l / d = 0.8 - 1.4, the ratio of length l to diameter of the slit is within l / d = 6 - 8 and the ratio of the center distance of two rows of spaced slots X to the diameter of the slit d is X / d = 1.9 - 2.6.

 The authors of the invention are not aware of similar technical solutions, and therefore, according to the authors, the proposed electric convector has significant differences.

 In FIG. 1 shows the proposed electric convector with a partial pullout, facilitating the explanation of the invention; in FIG. 2 is a diagram of a heating block of an electroconvector and a section AA of a diagram of a heating element; in FIG. 3 is a diagram of the lower panel of the convector and section BB; in FIG. 4 is a diagram of a top panel of an electric convector.

 The proposed electric convector (Fig. 1) comprises a housing 2 mounted on electrical insulating supports 1, heating elements 3 located inside the housing and connecting parts 4. A flow channel 5 is formed between the parallel heating elements (Fig. 2).

 On the bottom panel (Fig. 3), holes 6 are made through which air is sucked into the electric convector.

 On the top panel (Fig. 4) there are outlet openings 7 through which air heated in the electric convector enters the heated room.

 Electroconvector works as follows.

 After connecting the electric convector to the mains using the switch, the operating mode is set by connecting certain groups of heating elements. After heating the heating elements 3 (Fig. 1), cold air through the openings 6 of the lower panel enters the electric heaters 3, is heated and through the openings 7 of the upper panel enters the heated room.

The analysis of the influence of various factors on the efficiency of the electroconvector showed that the most important parameters, on which the efficiency of the electroconvector substantially depends, are:
the relative step of the heating elements t / H (Fig. 2), where H is the height of the heating element;
t is the step with which the heating elements are installed relative to each other;
the relative height of the heating element H / B (FIG. 2), where B is the width of the heating element;
step t of the heating elements related to the width B of the heating element, i.e. t / B (Fig. 2).

 The step t and the width B of the heating elements determine the cross-section of the flow channel 5 (Fig. 2), and therefore the air flow through the electroconvector, which determines the efficiency of the electroconvector.

 The height of the heating element H significantly affects the traction of the electric convector, air flow and its outlet temperature.

 Therefore, in the proposed electric convector, the heating elements are made with the ratio of the height H to the width B of the heating element in the region of optimal values of H / B, determined by the inequality 1.8 <H / B <2.2, the ratio of the step of the heating elements t to the width B of the heating element in the optimal range satisfying the inequality 1/4 <t / B <1/6, and are set with a relative step t / H in the region of optimal values limited by the inequality 1/11 <t / H <1/7.

 This embodiment and arrangement of the heating elements with a relative step of the inequality 1/11 <t / H <1/7 is explained by the need to ensure high efficiency of the electric convector.

 The execution on the lower and upper panels of three-row equal-sized slots ensures smoothness and uniformity of the air inlet into the electric convector and the uniformity of the air outlet from it into the heated room.

The distance between two adjacent rows l _p , referred to the diameter of the slot d, is made from the condition l _p / d = 0.8 - 1.4.

 The ratio of the length l to the diameter d of the slot is within l / d = 6 - 8, and the ratio of the center distance of two adjacent slots X to the diameter d of the slot is X / d = 1.9 - 2.6.

 The slots of the upper panel (Fig. 4) are identical in shape, size, aspect ratio and quantity to the slots of the lower panel (Fig. 3), i.e. the top panel is a mirror image of the bottom panel.

 The length of the heating block, composed, for example, of 16 heating elements, is L = 458 - 460 mm (Fig. 2). The ratio of the length L to the height of the heating element H is in the range L / H = 1.6 - 1.7.

All limits of the optimal values of the relative parameters H / B, t / B, t / H, l _p / d, l / d and X / d included in the claims are determined based on the data of the developed electroconvector.

 This embodiment of the convector increases its efficiency, since the hydraulic resistance of the flow channels and holes is sharply reduced.

где
∑ ΔH - суммарное гидравлическое сопротивление электроконвектора по тракту движения воздуха, Па;
ζ_n - коэффициент гидравлического сопротивления электроконвектора, который может быть приведен к любому сечению тракта;
ρ_ср - плотность воздуха при средней температуре в электроконвекторе, кг/м³;
W_ср - средняя скорость движения воздуха в проточном канале электроконвектора, м/с.Indeed, the hydraulic resistance of the electroconvector is determined by the formula [1] (p. 116):

Where
∑ ΔH is the total hydraulic resistance of the electroconvector along the air flow path, Pa;
ζ _n is the coefficient of hydraulic resistance of the electroconvector, which can be reduced to any section of the path;
ρ _cf - air density at an average temperature in the convector, kg / m ³ ;
W _cf - average air velocity in the flow channel of the electroconvector, m / s.

The values of ζ _n and W _cf are reduced to the same channel section.

Так как проточные каналы предлагаемого электроконвектора выполнены по форме и размерам одинаковыми и гидродинамически подобными между собой (фиг. 1-4), то коэффициенты сопротивления проточных каналов равны между собой, т. е.For parallel running flow channels by electro-hydraulic analogy, we can write

Since the flow channels of the proposed electroconvector are made in shape and size the same and hydrodynamically similar to each other (Fig. 1-4), the drag coefficients of the flow channels are equal to each other, i.e.

ζ ₁ = ζ ₂ = ... = ζ _k (3).

откуда

.Therefore, formula (2) will have the form

where from

.

 The resulting formula shows that the hydraulic resistance coefficient of an electroconvector equipped with flow channels arranged in parallel decreases inversely with the square of the number of flow channels.

т.е. коэффициент гидравлического сопротивления каналов электроконвектора уменьшается существенно.So, for example, with 15 parallel running channels (K = 15) and a channel resistance coefficient ζ ₁ = 14 [1] using formula (5) we get

those. the coefficient of hydraulic resistance of the channels of the electroconvector decreases significantly.

 In the case under consideration, in accordance with formula (1), the total hydraulic resistance of the electroconvector also decreases significantly.

где
Q_общ. - общий расход воздуха, м³/с;
K - число параллельно работающих проточных каналов;
S₁ - площадь поперечного сечения канала, м²;
∑ ΔH - разность давлений на входе и выходе электроконвектора, Па.In this case, the total air flow through the convector is equal to the sum of the costs passing through the parallel running channels. The total consumption is determined by the formula (1):

Where
Q _total - total air flow, m ³ / s;
K is the number of parallel flow channels;
S ₁ - the cross-sectional area of the channel, m ² ;
∑ ΔH is the pressure difference at the inlet and outlet of the electroconvector, Pa.

 The remaining notation is the same as in formula (1).

It can be seen from formula (6) that with decreasing ζ _n (all other conditions being the same), the air flow through the electric convector increases. As a result, the amount of heat used to heat the room air also increases.

 As a result, the air of the heated room to the optimum temperature heats up faster. This means increasing the efficiency of the electric convector.

где
η - КПД электроконвектора,%;
Q_вых - количество теплоты, идущее на нагрев воздуха помещения, Вт;
Q_п - теплопотери в помещении, Вт;
Q_подв. - количество теплоты, эквивалентное электроэнергии, подведенной к электроконвектору из электроисточника, Вт.The efficiency of the electroconvector, characterizing the degree of perfection of its design, is equal to

Where
η - efficiency of the electroconvector,%;
Q _o - the amount of heat used to heat the air in the room, W;
Q _p - heat loss in the room, W;
Q _sub. - the amount of heat equivalent to the electricity supplied to the electroconvector from the electric source, W.

.For a sealed room Q _p = 0. Therefore,

.

The greater the air flow through the convector, the greater the value of Q _o , and, according to formula (8), this leads to an increase in the efficiency of the convector, i.e. to increase the efficiency of his work.

 Thus, the distinguishing features of the present invention can significantly increase the efficiency and reliability of the electroconvector, i.e. achieve the objective of the invention.

 The optimal step of the heating elements ensures high efficiency of the electroconvector even if one of the heating elements fails for one reason or another. In this case, due to the mutual radiation of neighboring heating elements, the failed heating element is heated to the same temperature as the irradiating neighboring heating elements, as a result, the functionality of this element is restored, i.e. reliable operation of the electroconvector is provided.

 On the other hand, the optimal step of the heating elements determines the optimal dimensions of the flow channels, at which the throughput of the convector through the air is maximum and the hydraulic resistance is minimal, which ensures high efficiency of the convector.

In addition, the reliability and efficiency of the proposed electroconvector is ensured by the fact that it uses a low-temperature heating element (its surface temperature does not exceed 100 ^o C). This practically eliminates oxidative processes in the air and ensures fire safety. At a temperature of the order of 100 ^o C there is no thermal decomposition of dust and drying of the heated room air. Therefore, when the inventive electroconvector is created, a comfortable microclimate is created in the room.

 In the proposed electric convector, the temperature of the heated air is controlled by the number and connection diagram of the heating elements.

 Thus, the proposed electroconvector, due to the optimal combination of the essential combination of features set forth in the claims, provides high efficiency, reliability and safety of work, which makes it very competitive in the domestic and world markets.

Claims (1)

An electric convector comprising a box-shaped body with inlet and outlet openings, supports made of electrical insulating material, connected with supports, parallel heating elements with an electrically insulated substrate coated on one side with resistive material, united into groups on the busbars and connected to the mains via a switch, characterized in that in it the heating elements are made with the ratio of the height H to the width B of the heating element in the region of optimal N / V values, we determine inequality 1.8 <N / B <2.2, the ratio of the step t of the heating elements to the width B of the heating element in the optimal range satisfying the inequality 1/4 <t / B <1/6, and are installed with a relative step t / N in the region of optimal values, limited by the inequality 1/11 <t / H <1/7, while the upper and lower walls of the body are made in the form of panels located parallel to each other, on each of which holes are made in the form of three-row equal-sized slots, and the distance l _p between two rows, referred to the diameter of the slot d, sost It has l _p / d = 0.8 - 1.4, the ratio of the length l to the diameter d of the slot is within l / d = 6 - 8 and the ratio of the center distance X of two adjacent slots to the diameter d of the slot is X / d = 1 9-2.6.

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