RU191662U1 - The liquid heat exchanger of the thermoelectric module for heating air in agricultural premises - Google Patents

Abstract

The utility model relates to the field of agriculture, to the creation of a microclimate in agricultural premises, namely for heating air. The objective of the proposed utility model is to increase the efficiency of a liquid heat exchanger, to improve heat engineering parameters to increase the efficiency of the thermoelectric module for heating air in agricultural premises. the result of using the proposed utility model provides an increase in the efficiency of liquid heat transfer due to the fact that in the heat exchanger on the end side, the opposite side, where the two inlet pipes for liquid intake are located, an additional hole is made in which the outlet pipe through which the liquid exits is installed. The technical result is achieved by the fact that in the proposed liquid thermoelectric heat exchanger a module for heating air in agricultural premises, comprising a housing with a partition inside and two nozzles for fluid inlet and outlet, at one end second side of the housing has two inlet nozzle for fluid entering the heat exchanger flows in parallel along the walls and on the other end side of the housing opposite to that where the inlets are located, holds additional bore in which is mounted an outlet for exit of fluid from the heat exchanger.

Description

The utility model relates to the field of agriculture, to the creation of a microclimate in agricultural premises, namely for heating air.

One of the promising directions in the creation of new installations for air heating is the use of liquid heat exchangers for thermoelectric modules that provide effective heating of air in agricultural premises.

Known heat exchanger designed to remove heat from the cold and hot sides of the thermoelectric module, made according to the scheme "liquid - liquid" (PA Shostakovsky. Thermal control of objects based on thermoelectric modules. Components and technologies No. 9, 2011).

A disadvantage of the known heat exchanger is the limited heat transfer surface of the heat exchangers in contact with the air stream, significantly reducing the performance of the thermoelectric module for heating air in agricultural premises.

The closest in technical essence to the proposed utility model is a heat exchanger, which consists of a housing with inlet and outlet nozzles located on the front side of the heat exchanger housing, inside the housing there is a partition dividing the internal volume into two cavities, and on the other forms a passage for liquid from one cavity into another. The liquid enters the heat exchanger through one pipe, and leaves the other. Inside the case, parallel to the partition, there are cooling fins that increase the heat transfer surface of the thermoelectric module (https://dvrobot/ru/240/297/1111.html).

A disadvantage of the known heat exchanger is that during the passage of liquid inside the heat exchanger, heat is exchanged through the partition between two fluid flows towards each other: the oncoming fluid flow affects the outgoing fluid flow, thereby deteriorating the efficiency of the thermoelectric module for heating air in agricultural premises destination.

The objective of the proposed utility model is to increase the efficiency of a liquid heat exchanger, to improve the thermal parameters to increase the efficiency of the thermoelectric module for heating air in agricultural premises.

As a result of using the proposed utility model, the efficiency of the liquid heat exchanger is increased due to the fact that in the heat exchanger on the end side, the opposite side, where two inlet pipes for liquid intake are located, an additional hole is made in which an outlet pipe through which the liquid exits is installed.

The above technical result is achieved by the fact that in the proposed liquid heat exchanger of a thermoelectric module for heating air in agricultural premises, comprising a housing with a partition inside and two nozzles for inlet and outlet of liquid, according to a utility model, two inlet nozzles for liquid intake are installed on one end side of the housing into the heat exchanger in parallel flows along the partition, and on the other end side of the housing, opposite to where the inlet nozzles, an additional hole is made in which an outlet nozzle is installed for the liquid to exit the heat exchanger.

In the liquid heat exchanger on the end side, the opposite side, where two inlet nozzles for the fluid flow are located, an additional hole is drilled and an outlet nozzle is installed from which the fluid flow exits, while two fluid flows entering the heat exchanger flow along the partition separating the heat exchanger into two cavities, and exit the heat exchanger through an additionally installed outlet pipe. Two inlet pipes and an additional hole in the heat exchanger housing for the outlet pipe eliminates the presence of oncoming liquid flows in the heat exchanger, which entails an improvement in thermal performance.

The essence of the proposed utility model is illustrated in the drawing, which shows a general diagram of a liquid heat exchanger of a thermoelectric module for heating air in agricultural premises.

The liquid heat exchanger contains a housing 1, two inlet pipes 2, an outlet pipe 3, an additional hole 4, a partition 5 dividing the housing of the heat exchanger 1 into two cavities 6 and 7, cooling fins 8. Two inlet pipes 2 for liquid inlet are installed on one end face of the heat exchanger and on the opposite end side an additional hole 4 is made in which a pipe 3 is installed for the exit of the coolant.

The liquid heat exchanger operates as follows.

The fluid flow enters the heat exchanger through two inlet pipes 2. The fluid flow, divided into two equal in volume flow, moves parallel to the partition 5 and enters the cavity 6 and 7. The fluid flow in the cavities 6 and 7, passing along the partition 5 and cooling ribs 8 evenly heated (cooled). The liquid stream supplied through two inlet pipes 2 flows along the partition 5 dividing the thermoelectric module heat exchanger into two cavities 6 and 7. The liquid exits the heat exchanger through the outlet pipe 3, thereby eliminating the oncoming liquid flow in the heat exchanger.

The flows of liquid (water) in each cavity of the heat exchanger 6 and 7 are directed to one side parallel to the partition wall 5 of the heat exchanger and do not affect each other and exit the heat exchanger through the outlet pipe 3.

The proposed utility model allows the efficient use of thermoelectric modules with a liquid heat exchanger of the thermoelectric module for heating air in agricultural premises.

Claims (1)

A liquid heat exchanger of a thermoelectric module for heating air in agricultural premises, comprising a housing with a partition inside and two nozzles for liquid inlet and outlet, characterized in that two inlet pipes are installed on one end side of the housing for the liquid to enter the heat exchanger in parallel flows along the partition, and on the other end side of the housing, opposite to where the inlet pipes are located, an additional hole is made in which the outlet th nozzle for exit of fluid from the heat exchanger.

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