RU2566950C1 - Cooling device - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: cooling device comprising thermoelectric modules, one surface of which contacts with a cooling object, the other surface of thermoelectric modules - with a heat exchanger, and also a coolant circulation pump. Each of n ≥ 2 thermoelectric modules is equipped with its own heat exchanger, connected to the common cooling manifold via a pump (pumps) of coolant circulation.

EFFECT: improved thermal contact of surfaces of thermoelectric modules with heat exchangers.

4 cl, 2 dwg

Description

The invention relates to the field of refrigeration or freezing equipment.

Known refrigeration thermoelectric unit AH - ZhV - 250 - 12 (see crystalltherm.com> images / Katalogi / Catalog-2012.pdf) manufactured by NPO Kristall LLC, containing two or more thermoelectric modules installed on one side of a liquid heat exchanger, and the second side of the thermoelectric modules is in contact with the air radiator.

Also known is a liquid-liquid thermoelectric assembly 400-24-LL (see kryothermtec.com) manufactured by Kriotherm, in which thermoelectric modules contact their sides with liquid heat exchangers. The disadvantages of these devices are the great complexity of manufacturing a heat exchanger, completely adjacent to the surface of all thermoelectric modules, the second surface mounted on another heat exchanger, due to the technological spread of the height of the thermoelectric modules and the parallelism of their sides. The resulting gaps must be eliminated by means of heat-conducting pastes or glues, increasing thermal resistance, which, ceteris paribus, leads to a decrease in the temperature difference between the cold and hot sides and a decrease in the refrigeration coefficient as a whole.

A device for cooling is known from patent RU 2118759, IPC: F24F 3/14, F28D 7/00, G05D 22/00, selected as a prototype, containing thermoelectric modules, one surface of which is in contact with the cooling object, and the other surface of thermoelectric modules with a heat exchanger, as well as a pump for circulating the heat carrier through heat exchangers. Depending on the technological process of assembling the device, the manufacture of a condenser base or a liquid heat exchanger body is subject to requirements that ensure guaranteed thermal contact of the surface of all thermoelectric modules with either a condenser base during pre-installation of thermoelectric modules on a liquid heat exchanger or a liquid heat exchanger case when pre-installing thermoelectric modules on capacitor base.

Placing several thermoelectric modules between two heat-exchange surfaces to ensure thermal contact requires the use of a large number of elements that tighten these surfaces together, which leads to heat flow between the surfaces and a decrease in the temperature difference between the hot and cold sides of thermoelectric modules.

The technical result of the present invention is to improve the thermal contact of the surfaces of thermoelectric modules with heat exchangers while simplifying the manufacturing process of heat exchangers and attaching thermoelectric modules between them.

The specified technical result is achieved due to the fact that in the cooling device containing thermoelectric modules, one surface of which is in contact with the cooling object, and the other surface of thermoelectric modules is in contact with the heat exchanger, as well as the heat transfer pump, in contrast to the known one, each of n≥2 thermoelectric modules is equipped with its own heat exchanger connected to a common cooling line through a circulation pump.

In the cooling device, it is proposed that each thermoelectric module be equipped with a compression unit to the cooling object made in the form of a flat spring, one end of which is fixed to the cooling object, and the second end is pressed against the cooling side of the thermoelectric module.

In the cooling device, it is proposed that each heat exchanger in contact with the hot side of the thermoelectric module be equipped with a preload unit to the thermoelectric module made in the form of a flat spring, one end of which is fixed to the heat exchanger and the other end is pressed to the hot side of the thermoelectric module.

In the cooling device, it is proposed to turn on the coolant circulation pump through heat exchangers in series with heat exchangers, also connected in series, while the flow-pressure characteristics of the coolant circulation pump through heat exchangers are determined from the relation

ΔT = T ₁ -T _p / T ₁ ≤ΔQ, where:

ΔT is the temperature difference of the coolant at the inlet of the first and outlet of the last heat exchangers;

T ₁ - temperature of the coolant at the inlet of the first heat exchanger;

T _p - the temperature of the coolant at the outlet of the last heat exchanger;

ΔQ - tolerance for cooling capacity of thermoelectric modules.

This invention is relevant when the number of thermoelectric modules used is more than one, since with one module there are no problems with providing thermal contact of the common heat exchanger and modules differing in height and with non-parallel sides.

Improving the thermal contact of the surfaces of thermoelectric modules with heat exchangers is solved by the fact that the individual heat exchanger of each thermoelectric module eliminates the influence of their technological spread in height and non-parallel sides, while ensuring the required cleanliness of the surface treatment in contact with the thermoelectric module. With a standard tolerance on the height of the thermoelectric module ± 0.02 mm and non-parallelism ± 0.02, the gap between the surface of the heat exchanger and the thermoelectric module of lower height can reach 0.06 mm in the middle of the thermoelectric module 40 × 40 mm in size. In the case of using the widely used heat-conducting paste KPT-8 with a thermal conductivity coefficient of 0.8 W / m * K and a heat flux through a 50 W thermoelectric module, 2.3 ° C will be lost in this gap.

All other things being equal, the use of flat springs is aimed at increasing the temperature difference of the surfaces of thermoelectric modules, which completely eliminate the flow of heat along the elements that tighten the surfaces between which the thermoelectric modules are located.

The invention is illustrated in FIG. 1, which shows the structure of a device with heat exchangers for each thermoelectric module, and FIG. 2 shows the assembly I in FIG. one.

Moreover, in FIG. 1 presents: thermoelectric modules 1 of different heights and relative positions of surfaces, one surface of which is in contact with the cooling object 2, and the other surface of thermoelectric modules with heat exchangers 3 connected in series, as well as pump (s) 4 of the heat carrier circulation through heat exchangers connected to a common cooling line 5. In general, a device can have several groups of heat exchangers and a pump connected in series with each other.

Moreover, each thermoelectric module 1 is attached to the cooling object 2 using flat springs 6, one end of which is fixed with fastening elements 7 to the cooling object, and the second end presses the cooling side of the thermoelectric module to the cooling object. Moreover, each heat exchanger 3, which removes heat from the hot side, is attached to the thermoelectric module 1 using flat springs 6, one end of which is fixed using fastening elements 7 on the heat exchanger, and the second end presses the hot side of the thermoelectric module to the heat exchanger.

Flat springs 6 using fastening elements 7 provide thermal contact of the surfaces of thermoelectric modules 1 with the cooling object 2 and heat exchangers 3, regardless of the height of the thermoelectric modules and the non-parallelism of their sides.

The proposed device operates as follows. A heat exchanger 3 is attached to the hot surface of each thermoelectric module 1 using flat springs 6 and fastening elements 7. Thermoelectric modules 1 with heat exchangers 3 attached to them are attached to the cooling object 2 using flat springs 6 and fastening elements 7. Hydraulic lines are connected in series with each other heat exchangers 3 and connect them through the pump 4 to the cooling line 5. The required flow rate through the heat exchangers is ensured by the fact that the flow-pressure characteristics and pump 4 is determined from the ratio

ΔT = T ₁ -T _p / T ₁ ≤ΔQ, where:

ΔT is the temperature difference of the coolant at the inlet of the first and outlet of the last heat exchangers;

T ₁ - temperature of the coolant at the inlet of the first heat exchanger;

T _p - the temperature of the coolant at the outlet of the last heat exchanger;

ΔQ - tolerance for cooling capacity of thermoelectric modules.

In the case when the value of the difference ΔT between the temperature of the coolant at the inlet of the first T ₁ and the output of the last T _{p of} heat exchangers connected in a series circuit related to the temperature of the coolant at the inlet of the first heat exchanger T ₁ from the common cooling line does not exceed the tolerance for cooling capacity ΔQ , which is indicated in the technical documentation for the modules, we can neglect the influence of the temperature difference of the surfaces of thermoelectric modules on their cooling capacity.

The thermal contact of the surface of each thermoelectric module with the cooling object is ensured by the fact that each thermoelectric module is attached to the cooling object using flat springs, one end of which is fixed to the cooling object, and the second end presses the cooling side of the thermoelectric module to the cooling object. The thermal contact of the other surface of the thermoelectric module with the heat exchanger is ensured by the fact that each heat exchanger that removes heat from the hot side is attached to the thermoelectric module using flat springs, one end of which is fixed to the heat exchanger, and the other end presses the hot side of the thermoelectric module to the heat exchanger.

The use of individual heat exchangers 3 for each thermoelectric module 1 reduces the requirements for tolerances on the geometric dimensions of thermoelectric modules in the process of their production, and in combination with pressing thermoelectric modules 1 with flat springs 6 with fastening elements 7 provides thermal contact of any number of thermoelectric modules with cooling object 2 and heat exchangers 3. The use of pumps 4, providing circulation of the coolant through each group of n are connected in series 3 heat exchangers from the cooling pipe 5, eliminates non-uniform distribution of coolant through the heat exchangers 3 group because of the spread of hydraulic resistance arteries.

The proposed cooling device guarantees thermal contact of the surfaces of thermoelectric modules with the cooling object and heat exchangers, reduces the cost of manufacturing high-quality heat exchangers, simplifies the assembly of the cooling device, guarantees uniform heat removal from the hot sides of thermoelectric modules, thereby increasing cooling capacity or reducing the number of required thermoelectric modules.

Claims (4)

1. A cooling device containing thermoelectric modules, one surface of which is in contact with the cooling object, and the other surface of thermoelectric modules is in contact with a heat exchanger, as well as a coolant circulation pump, characterized in that each of n≥2 thermoelectric modules is equipped with its own heat exchanger connected to a common cooling line through the coolant circulation pump (s). 2. The cooling device according to claim 1, characterized in that each thermoelectric module is equipped with a compression unit to the cooling object, made in the form of a flat spring, one end of which is fixed to the cooling object, and the second end is drawn to the cooling side of the thermoelectric module. 3. The cooling device according to claim 1, characterized in that each heat exchanger in contact with the hot side of the thermoelectric module is equipped with a preload unit to the thermoelectric module made in the form of a flat spring, one end of which is fixed to the heat exchanger, and the second end is pressed to the hot side thermoelectric module. 4. The cooling device according to claim 1, characterized in that the pump (s) for circulating the heat carrier through the heat exchangers is connected (s) in series with the heat exchangers also connected in series, and the flow-pressure characteristics of the pump (s) for circulating the heat carrier through the heat exchangers are determined from the relation
ΔT = T ₁ -T _p / T ₁ ≤ΔQ, where:
ΔT is the temperature difference of the coolant at the input of the first and output of the last heat exchangers,
T ₁ - temperature of the coolant at the inlet of the first heat exchanger,
T _p - the temperature of the coolant at the outlet of the last heat exchanger,
ΔQ - tolerance for cooling capacity of thermoelectric modules.

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