RU2098724C1 - Evaporation refrigerator - Google Patents

Abstract

FIELD: cryogenic engineering; solid-state physics, nuclear physics, space engineering and refrigerating engineering. SUBSTANCE: heat exchange surface of refrigerator is formed by vertical heat- conducting plates; each plate is made in form of backing with heat-conducting filaments secured vertically on it and tightly positioned relative to one another forming capillary-filamentary structure which considerably increases evaporation surface of refrigerant and heat exchange surface with heat conducting plates due to capillary raising of liquid. Thin film of evaporated liquid refrigerant on considerably increased heat exchange surface provides for high rate of evacuation, enhances heat transfer, thus increasing refrigerating capacity with no change in volume of evaporation chamber and amount of liquid refrigerant. EFFECT: increased refrigerating capacity. 3 dwg

Description

 The invention relates to cryogenic technology, in particular to ultra-low temperature technology, and can be used in the field of solid state physics, nuclear physics, space technology and the refrigeration industry.

A number of evaporation refrigerators are known, based on pumping out saturated vapor of a liquid refrigerant, for example liquid ³ He, in which the evaporation chamber is a container of heat-conducting material filled with liquid refrigerant. The main disadvantage of refrigerators of this type is that the cold formed on the evaporation surface is transferred to the walls of the chamber (and through them to the cooled object being in thermal contact with them) through a layer of liquid refrigerant, whose thermal conductivity is quite low. This limits the cooling capacity of the device and the minimum achievable temperature.

In the case of using ³ He as a refrigerant in the temperature range below 0.5 K, heat transfer through the liquid layer is further deteriorated by the absence of convection due to the inversion of the coefficient of thermal expansion. As a result, the main surface area of the evaporation is blocked (thermally insulated) and evaporation occurs only with a narrow strip of the surface (about 1 mm wide), localized around the perimeter of the chamber near its vertical wall. Thus, the evaporation surface participating in the cold generation process is sharply reduced, which leads to a further decrease in the refrigerating capacity of the refrigerator.

 Also known is the evaporation refrigerator, the closest in technical solution to the claimed one and adopted as a prototype, containing an evaporation chamber with a developed heat-exchange surface formed by vertical heat-conducting plates in thermal contact with the camera body.

 The presence of these plates located at a fairly close distance from each other (less than 1 mm) ensures the supply of heat to all parts of the surface of the liquid refrigerant. As a result, evaporation occurs from the entire surface area and the refrigerating capacity of the refrigerator increases. The main limiting factors in this case are the final evaporation surface area, determined by the size of the chamber (specifically its diameter), and the thermal resistance at the boundaries of the plates with liquid refrigerant (the so-called Kapitsa resistance), which increases sharply with decreasing temperature.

However, a significant drawback of this design is that the main part of the heat exchange surface of the plates in contact with liquid ³ He, due to its poor thermal conductivity, is blocked and practically does not participate in the heat transfer process, so that the entire heat flux is removed only from small sections of the height of the plates located directly below the liquid level in the chamber in a liquid layer with a depth of about 1 mm. As a result, the refrigerating capacity of refrigerators of this type at temperatures below 0.5 K does not exceed 10 ^-4 -10 ^-5 W.

 The main objective of the proposed technical solution is to increase the refrigerating capacity of the refrigerator by increasing both the heat transfer surface of the plates in the immediate vicinity of the evaporation surface of the liquid refrigerant and the evaporation surface itself.

 This problem is solved by using the capillary effect, which allows you to transport a thin film of liquid to a considerable height above the level of refrigerant in the chamber, regardless of the position of the level itself. The surface of this film creates an additional evaporation surface of the refrigerant, and the film-coated surface of the heat transfer plates is effectively included in the heat transfer due to the small thickness of the film.

где d диаметр нити, м;
α поверхностное натяжение жидкого хладоагента, H/м;
r плотность жидкого хладоагента, кг/м³;
g ускорение силы тяжести, м/с²;
h высота капиллярного поднятия жидкости, м;
d зазор между нитями, м.To do this, in a refrigerator containing an evaporation chamber, the heat exchange surface of which is formed by vertical heat-conducting plates in thermal contact with the chamber body and with liquid refrigerant, the latter are made in the form of a substrate with heat-conducting threads fixed vertically and close to each other, for example, from copper wire, and the diameter of the threads (d) and the gap between the threads δ are selected from the following ratios:

where d is the diameter of the thread, m;
α surface tension of the liquid refrigerant, N / m;
r the density of the liquid refrigerant, kg / m ³ ;
g acceleration of gravity, m / s ² ;
h the height of the capillary rise of the liquid, m;
d the gap between the threads, m

 The height of the capillary rise (h) is set based on the required refrigerating capacity of the refrigerator and can be equal to the total height of the heat-conducting plates, and theoretically even exceeds it.

 Due to this design, due to surface tension, the liquid refrigerant rises to a considerable height above the liquid level in the chamber and forms a thin layer of liquid refrigerant on the surface of the heat-conducting plates, from which it evaporates, followed by cooling. The larger the evaporation surface and, accordingly, the heat transfer surface of the plate, covered with a thin film of liquid refrigerant, the greater the heat removal and, therefore, the higher the refrigerating capacity of the refrigerator.

 In FIG. 1 shows an evaporation refrigerator (diagram); in FIG. 2 plate with heat-conducting threads (general view); in FIG. 3 plate with heat-conducting threads, top view.

The evaporation refrigerator (Fig. 1) contains an evaporation chamber 1 filled with liquid refrigerant 2 (for example, ³ He), the internal cavity of which is connected by a nozzle 3 to a vacuum pump (not shown in the drawing), and a cooled object 4, placed in a heat-insulated casing 5, immersed in a bath 6 with liquid refrigerant 7, for example ⁴ He.

, выполненными в виде подложки 9, например, из медной фольги, с закрепленными на ней вертикально и вплотную друг к другу с зазором δ теплопроводными нитями 10, например, из медной проволоки диаметром d (см. также фиг. 2 и 3), образующими на поверхности пластин капиллярно-нитевую структуру.The heat exchange surface 8 of the evaporation chamber 1 is formed by heat-conducting plates of height H and length l _i , making up the total total length

made in the form of a substrate 9, for example, of copper foil, with heat-conducting threads 10 fixed vertically and close to each other with a gap δ, for example, of copper wire of diameter d (see also Figs. 2 and 3), forming on the surface of the plates is a capillary-thread structure.

 Depending on the required technological parameters of the refrigerator, it is possible to fix the threads 10 on the substrate 9 both on one or both sides.

 The evaporation surface is formed by both the level 11 of the liquid refrigerant 2 in the evaporation chamber 1 and the surface 12 of the liquid refrigerant film (Fig. 2) that occurs on the outer side of the heat-conducting plates 8 when the liquid refrigerant is capillarily raised in the channels between the heat-conducting threads 10 and the substrate 9 to a height h.

 The refrigerator operates as follows.

When filling the chamber 1 with liquid refrigerant 2 (Fig. 1), for example ³ He, the liquid level between the heat-conducting threads 10 and the substrate 9 in the capillary-thread structure rises above the level of the liquid 11 in the chamber 1 by an amount h (Fig. 2) with the formation of the outer surface of the meniscus system.

After pouring the liquid, a vacuum pump is switched on (not shown in the drawing) and through the pipe 3 they pump ³ He vapor with absorption of thermal power proportional to the heat of vaporization of liquid ³ He.

 Produced cold through the heat exchange surface 8 is transferred to the housing of the chamber 1 and the cooled object 4.

During the pumping process, the presence of a certain gap d between the threads 10 provides constant replenishment of the meniscus system on the outer surface of the capillary-thread structure, due to which the surface of the liquid evaporation surface 12 increases and, accordingly, the heat transfer surface of the liquid ³ He increments in the chamber 1. With a decrease in the level of 11 liquid refrigerant in chamber 1, the value of the evaporation surface continues to remain unchanged until the chamber 1 is completely emptied due to the constancy of the height of the capillary rise of the liquid h, at The heat transfer surface also remains constant throughout the entire pumping period.

 This ensures the stability of the temperature in the chamber at a constant pumping speed.

 In the case when the pumping speed cannot be kept constant throughout the entire pumping period, for example, in the case of using an adsorption pump, the decrease in the pumping speed as the adsorbent is saturated can be partially compensated by providing an excess liquid rise in the capillary-thread structure by the proper choice of the diameter of the threads.

 In this case, h is chosen to be equal to or greater than the total height of the heat-conducting plate H, and then the height of the liquid in the capillary-thread structure is set at the upper edge of the plate, regardless of the position of the level 11 of the liquid refrigerant in the chamber 1, which obviously leads to an increase in the evaporation surface and the heat transfer surface during pumping as the fluid level in the chamber decreases.

 For a complete presentation of the invention, an example of a specific implementation of the proposed refrigerator.

For comparison, we took a refrigerator with an evaporation chamber with a diameter of 0.05 m, in which the heat exchange surface is made in the form of vertical plates with a height of H = 0.02 m and a total length of L = 1.375 m. The area of the plates is 0.055 m ² . In this case, the fraction of the surface that is effectively participating in heat transfer and is localized below the liquid level in the chamber to a depth of 1 mm on both sides of the plate will be 0.00275 m ² , regardless of the level of liquid in the chamber.

а величина зазора между нитями δ определится из неравенства:

откуда для δ получим: 8•10^-6м < d ≅ 75•10^-6м (8 75 мин). Количество нитей в слое на суммарной длине L составит:

, на обеих сторонах подложки 4600.In the proposed design of the refrigerator, while maintaining the same geometric dimensions of the chamber and the total length of the heat exchange surface L = 1,375 m, the latter is made in the form of a thin substrate with a double-sided capillary-thread structure, the parameters of which provide a capillary rise of the liquid to a height h = 5 mm above the liquid level in the camera. The diameter of the filaments is determined from the ratio d = 16α / ρgh ,, where α 1.5 • 10 ^-4 H / m, r 82.2 kg / m ³ (both values for ³ He at a temperature of 0.4 K), g 9.81 m / s ² , h 5 • 10 ^-3 m selected value. From here:

and the gap between the threads δ is determined from the inequality:

whence for δ we get: 8 • 10 ^-6 m <d ≅ 75 • 10 ^-6 m (8 75 min). The number of threads in the layer on the total length L will be:

, on both sides of the substrate 4600.

4,4•10^-3 м². Таким образом, суммарная теплообменная поверхность в предлагаемой конструкции рефрижератора будет равна 10^-2 м² + 4,3•10^-3 м² 1,43•10^-2 м², что в 5,2 раза превышает теплообменную поверхность рефрижератора, принятого для сравнения. Соответственно во столько же раз возрастет холодопроизводительность рефрижератора на том же температурном уровне.Based on the above conditions, the increment of the liquid evaporation surface due to the use of a capillary-thread structure on both sides of the substrate is estimated to be 4.16 • 10 ^-3 m ² , which is twice the surface area of the liquid in the chamber. The area of the refrigerated surface of the refrigerator covered with a film of liquid refrigerant is equal to 10 ^-2 m ² , and the heat exchange surface effectively participating in the heat transfer in the liquid layer 1 mm deep below the level in the chamber will increase with respect to this value for the refrigerator used for comparison (2.75 • 10 ^-3 m ² ) π / 2 times f (by the value of the total external surface of the wires in this layer) and will be

4.4 • 10 ^-3 m ² . Thus, the total heat exchange surface in the proposed design of the refrigerator will be equal to 10 ^-2 m ² + 4.3 • 10 ^-3 m ² 1.43 • 10 ^-2 m ² , which is 5.2 times higher than the heat transfer surface of the refrigerator, adopted for comparisons. Accordingly, the refrigerating capacity of the refrigerator will increase by the same amount at the same temperature level.

Thus, the technical result, expressed in increasing the cooling capacity of the proposed device, is provided by the following:
the presence of filaments creates a capillary-thread structure of heat transfer plates, consisting of vertically arranged channels in which, due to the capillary effect, the level of liquid refrigerant is much higher than its level in the chamber;
the presence of certain gaps between the threads ensures leakage of liquid refrigerant to the outer side of the capillary-thread structure, with the formation on it of an additional surface of evaporation of the refrigerant;
portions of the capillary-thread structure covered with a thin film of liquid refrigerant create an additional heat exchange surface between the liquid refrigerant and the heat-conducting plates, and the effectiveness of this surface is ensured by the small thickness of the film covering it;
a significant (several-fold) increase in the evaporation and heat transfer surfaces in a limited chamber volume significantly increases the refrigerating capacity of the refrigerator.

Claims (1)

Evaporating refrigerator based on pumping out saturated vapor of a liquid refrigerant, containing an evaporation chamber, the heat exchange surface of which is formed by vertical heat-conducting plates in thermal contact with the chamber body and liquid refrigerant, characterized in that each plate is made in the form of a substrate with vertically and vertically fixed to it close to each other with heat-conducting threads, and the diameter d of the threads and the gap δ between the threads are selected from the following relationships:

where α is the surface tension of the liquid refrigerant, N / m;
ρ is the density of the liquid refrigerant, kg / m ³ ;
g acceleration of gravity, m / s ² ;
h the height of the capillary rise of the liquid, m

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