RU2059946C1 - Heating radiator - Google Patents

Abstract

FIELD: heat-power engineering; water heating systems. SUBSTANCE: heating radiator is provided with inlet and outlet headers interconnected by means of row of heat-exchange elements made of heat-resistant tubes 1 mounted horizontally in vertical steel headers 2 and 3 provided with transverse partitions which divide each header into two unequal parts. Arranged between glass tubes 1 are profiled turbulizing plates 7; each glass tube 7 is connected with steel header by means of gland joint which has branch pipe with external thread, main bush, nut and sealing gasket made of heat-resistant rubber. EFFECT: enhanced efficiency. 3 dwg

Description

 The invention relates to a power system and can be used in water heating systems.

Known heating radiator containing a series of vertical plastic tubes connected to prefabricated plastic collectors equipped with extruded jumpers with spacer plugs inserted into them for mounting the heater to the wall [1]
A disadvantage of the known device is that plastic heaters have a significant thermal expansion, as a result of which it is necessary to provide for the installation of expansion joints. The heat exchange surface, consisting of a series of vertical tubes, has longitudinal washing, as the plastic heating radiator operates under conditions of natural convection, as a result of which the heat transfer coefficient from the outer surface of the radiator to the room air is very low. A plastic radiator has a low coefficient of thermal conductivity of 0.0004-0.0007 cal / cm · sec / deg, which entails a low coefficient of heat transfer. The manufacturing technology of extruded jumpers and the entire structure as a whole is complex.

Also known is a heating radiator comprising a housing made of two parts hermetically connected to each other in the horizontal plane of the connector, with the formation of interconnected chambers for the passage of coolant, the housing is equipped with an external fin in the form of alternating protrusions and depressions, the inner surface of the chambers being made smooth, and all the protrusions and depressions of the fins are made equal in height [2]
A disadvantage of the known heating radiator is that only the upper part of the protrusions is relatively efficient in it, while in the troughs there are stagnant zones with very low air circulation, as a result of which the known radiator has a low heat transfer coefficient. The design of the known radiator does not allow reliable sealing of two parts of the radiator in the horizontal plane of the connector.

Known heating radiator M-140, including horizontal inlet and outlet manifolds interconnected by a number of vertical heat exchange elements [3]
Known cast-iron heating radiator has a number of significant disadvantages. Installation of cast-iron radiators is a very time-consuming process and is in conflict with industrial methods of building construction. Cleaning the surfaces of the radiator is difficult, as a result of which dust may burn on them. In addition, well-known radiators degrade the interior of the premises. The latter is especially significant in connection with a decrease in the thickness of the outer fencing, which makes it impossible to arrange niches in them to accommodate radiators. The large cross-section of the parallel-connected sections of cast-iron radiators and the insignificant flow rate of the coolant with its normative parameters (t _g 95 ^о С; t _o 70 ^о С) determine the negligible hydraulic resistance of cast-iron radiators, of the order of no more than 1 kgf / m ² (≈10 Pa ) for building heating conditions. However, to link the hydraulic resistances of the circulation rings of the risers with cast-iron radiators having insignificant hydraulic resistance, it is necessary to select different pipe diameters for the falling and return pipes, risers and inlets to the radiators. The presence in the heating system of different diameters of pipes entails a significant increase in the complexity of procurement and installation work, since you have to deal with a large number of sizes of nodes and parts of pipelines. The insignificant hydraulic resistance of cast-iron radiators is one of the main reasons for the hydraulic and thermal deregulation of central heating systems in high-rise buildings, which increases with decreasing outdoor temperature.

к

рад или где Q количество тепла, отдаваемого прибором в ккал/ч или вт;
G масса прибора в кг;
Δt разность средних температур поверхности прибора и окружающего воздуха (t_пр. t_в.).The criterion for the heat engineering and technical and economic evaluation of a heater is the thermal voltage q appliance material that is a unit heat transfer with the difference in average temperature of the device surface and the ambient room air at 1 ^{° C,} referred to its weight (iron radiator mass M-140 from seven sections 53.2 kg) [3]
q

to

glad or where Q is the amount of heat given off by the device in kcal / h or watts;
G mass of the device in kg;
Δt is the difference between the average temperatures of the surface of the device and the ambient air (t _ave. T _century ).

0,28
ккал/кг·ч·град или Вт/кг·град
Как видно из приведенного расчета, тепловое напряжение материала радиатора М-140 очень низкое. В связи с этим на чугунные радиаторы М-140 расходуется большое количество металла, т.е. около 65-70% от общего веса металла, расходуемого на устройство системы отопления в целом.The greater the thermal voltage of the material of the heater, the more profitable it is. Standard cast iron radiator M-140, consisting of seven sections, has a heating surface of 1.78 m ^2, the heat transfer coefficient of 8.4 kcal / m ² · h · deg (3), Δt average temperature difference with the surface and the ambient (t _ave t _c ) (82.5 18) 64.5. Then q is
q

0.28
kcal / kg · h · deg or W / kg · deg
As can be seen from the above calculation, the thermal voltage of the material of the radiator M-140 is very low. In this regard, a large amount of metal is consumed on cast-iron radiators M-140, i.e. about 65-70% of the total weight of the metal spent on the device of the heating system as a whole.

 From the dissertation of N. F. Parfenov, “Investigation of the heat transfer process in heating devices, central water heating systems” (Belarusian Polytechnic Institute, Minsk), it was established that when the coolant is supplied in a radiator of type M-140, the coolant moves along the axis of the sections, forming a flow core . Under conditions of a laminar regime of fluid motion, heat is transferred from the core of the flow to the surface of the radiator through thermal conductivity through a thick layer of liquid, which helps to reduce the temperature towards the surface. Radiators made of metal are athermal for heat rays and have a low degree of blackness. The M-140 radiator is finned, which reduces its efficiency compared to a non-finned surface, this position is obvious, since the fin efficiency is determined not only by convective heat transfer, but also by the thermal resistance of the fin.

 In addition, the fins and the heating surface of the radiator are washed by a longitudinal stream of air, and therefore have a low heat transfer coefficient.

Known heating radiator containing input and output collectors communicated with each other through horizontal heat-resistant glass pipes [4]
This device contains the largest number of common design features with the proposed device and is considered as a prototype.

 An object of the invention is to increase the heat transfer coefficient.

 The technical problem is solved due to the fact that in the heating radiator, including the input and output collectors, interconnected by a series of heat-exchange elements of heat-resistant glass pipes mounted horizontally, vertical steel collectors are used, equipped with transverse partitions that divide each collector into two unequal parts, between glass tubes of heat-exchange elements are placed profiled turbulizing plates, and each glass pipe is connected to a steel collector by redstvom packing compound containing interconnected pipe with an external thread, the packing follower, waybill nut and a gasket of heat-resistant rubber.

 In FIG. 1 shows a proposed heating radiator, front view; in FIG. 2 same, top view; figure 3 gland connection of glass pipes with steel manifolds.

 The radiator contains heat-resistant glass pipes 1 of composition 13 v, left steel manifold 2, right steel manifold 3, partitions 4, stuffing box 5, air discharge cock 6, profiled turbulence plates 7. Packing 5 consists of a steel pipe 8 with external thread, packing followers 9, nut overlay 10 and gasket 11 made of heat-resistant rubber.

 Glass heating radiator operates as follows.

≥ 1

где F_к площадь поперечного сечения коллектора;
Σf_тр суммарная площадь проходного сечения трубного пучка, что обеспечивает равномерный расход воды по стеклянным трубкам 1, а следовательно, и равномерный их нагрев, отсутствие застойных зон и равномерную постоянную скорость воды в трубах.Collectors 2 and 3 with the help of partitions 4 are divided into two parts. Hot network water from the water heating system enters the upper part of the left collector 2, and then through eight glass pipes 1 enters the upper part of the right collector 3, in which, turning 180 ^about eight glass pipes 1, enters the lower part of the left collector 2, wherein, in making turn ^180, fed by eight glass pipe 1 in the lower right portion of the reservoir 3, which enters the reverse heating line. Thus, the glass radiator has three strokes. Since the cross-sectional area of the collector in the radiator is larger than the total passage area of the tube bundle, i.e. the condition is satisfied

≥ 1

where F _to the cross-sectional area of the collector;
Σf _{tr is the} total flow area of the tube bundle, which ensures uniform water flow through the glass tubes 1, and consequently, their uniform heating, the absence of stagnant zones and uniform constant water velocity in the pipes.

 The radiator operates in conditions of natural convection, therefore the glass pipes 1 located horizontally have a transverse washing, and the heat transfer coefficient from the pipes to the air is higher than the longitudinal washing. In the middle between the glass pipes 1, profiled turbulizing plates 7 are placed, which create wave-like channels for the passage of air from bottom to top, as a result of which the heat transfer process is greatly intensified.

The radiator has the following advantages compared to the cast iron radiator M-140. We accept (as a first approximation) heat-resistant glass pipes of composition 13 in 33 x 2.5; transverse pipe pitch S ₁ 47 mm; longitudinal pitch S ₂ = 46 mm; length of glass pipes 500 mm; number of pipes in one stroke 8 pcs; diameter of steel collectors 89 x 3.

According to these sizes, we determine the dimensions of the radiator: height 558 mm; length 678 mm; width 89 mm. The mass of the metal part of the radiator is 9.8 kg, and the mass of the glass part of the radiator is 6.5 kg, i.e. the total mass of the radiator is 16.3 kg. The heat transfer coefficient of 20 kcal / m ² · h · deg (or W / m ² · deg). The heat transfer coefficient was determined during heat engineering tests in the laboratory of the Voronezh Civil Engineering Institute at the Department of Heat Engineering, Gas Supply and Ventilation under the guidance of prof. G.E. Kholodovsky. The test was subjected to a full-scale sample of a heating device made of heat-resistant glass pipes of 13 V. The tests were carried out in accordance with the standard program and standard methodology.

2,22
ккал/кг·ч·град или Вт/кг·град.According to the above dimensions, the heating surface of the radiator is calculated, which is 1.81 m ² . According to the above indicators, we determine the thermal voltage of the glass radiator material as
q

2.22
kcal / kg · h · deg or W / kg · deg.

 Comparing the thermal voltage of the materials of the cast-iron radiator M-140, equal to 0.28, and the glass radiator, equal to 2.22 kcal / kg · h · deg (or W / kg · deg), we see that the thermal voltage of the material of the glass radiator is greater than almost the cast-iron 8 times, which entails a tremendous saving of metal, fuel and cash.

 Heat-resistant glass pipes with a composition of 13 V are diathermic bodies for heat rays, so the radiant component in the heat transfer coefficient increases sharply. Based on this, it is recommended to place glass radiators in the upper parts of buildings. Glass pipes have a greater degree of blackness compared to cast iron. The degree of blackness of glass pipes is ε = 0.94, and cast iron ε = 0.71.

 As follows from the above, the processes of heat transfer from the heating surface of glass pipes proceed much more intensively than from cast iron. Glass pipes have a lower absolute roughness compared to pipes made of cast iron, as can be seen from the following data: glass pipes 0.0015; cast iron new 0.15-1 mm.

 The glass radiator from the point of view of sanitary and hygienic requirements is very promising, as it will create good microclimatic conditions in the room, its surface is smooth and easily accessible for inspection and dust removal.

Glass radiator can be assembled with any heating surface and any hydraulic resistance. The density of glass pipes is 2.2–2.7 g / cm ³ , and that of cast iron 7.8–7.9 g / cm ³ and, therefore, a glass radiator with the same wall thickness will be about 4 times lighter than cast iron. The transparency of glass pipes allows you to visually monitor the flow of liquid and eliminate various contaminants, monitor the regime of fluid movement (laminar or turbulent), speed, presence of air bubbles, etc.

 Due to the high corrosion resistance of glass pipes, there is practically no increase in their resistance during operation. The resistance coefficient of glass pipes is 10-12% lower than metal. Pipes made of heat-resistant glass are about 3 times cheaper than steel.

Claims (1)

 A heating radiator comprising inlet and outlet manifolds interconnected by horizontal heat-resistant glass pipes, characterized in that the collectors are made in the form of vertical steel cylinders, in the cavity of each of which is a dividing wall with the formation of two unequal parts of the collector, and glass pipes are located in two parallel vertical planes and between them profiled turbulizing plates are installed, with each glass pipe connected to steel nym collector through the packing compound containing interconnected pipe with an external thread, the packing follower, waybill nut and a gasket of heat-resistant rubber.

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