RU194750U1 - Plate heat exchanger element for supply and exhaust ventilation systems - Google Patents

Abstract

The invention relates to a device for heat recovery, namely to plate heat exchangers for supply and exhaust ventilation systems. The technical result of the utility model is to simplify the design, increase its efficiency and reduce the rigidity of the material used. The technical result is achieved in that in the element of the plate heat exchanger for systems of supply and exhaust ventilation, comprising a housing and a set of heat transfer plates made with the possibility of installation in a stack, according to the useful m For this, two types of heat exchanger plates with perimeter edges were used, the inlet and outlet slots of which are made in the form of cutouts in the end walls of the heat exchanger plates, while for the first type of heat exchanger plates, the air inlet gap is made on the end part on the left, and the outlet slit on the end part on the right, and for heat exchanging plates of the second type, the inlet slit for air is made on the end part on the right, and the output slit is on the end part on the left, heat exchangers of the first and second types are stacked alternately, overhealing each heat transfer plate is installed purged stiffener that protects the device from collapsing.

Description

The utility model relates to a device for heat recovery, namely to plate heat exchangers for supply and exhaust ventilation systems.

According to patent RU 129617, a plate-parallel heat exchanger element for supply and exhaust ventilation systems is known, including a flat hexagonal frame with first, second, third, fourth, fifth and sixth consecutive sides, and containing internal partitions, and adapted for fastening to it heat transfer plates, characterized in that the flat frame includes at least one groove on its first side and at least one groove on its fourth side, and at least one a protrusion on its second side, and at least one protrusion on its fifth side, and the protrusions are adapted to enter the grooves, and the grooves are adapted to enter these protrusions when assembling elements of the plate heat exchanger in the package, and the fact that these grooves and protrusions adapted for fixing heat transfer plates.

The disadvantages of the known device is the design complexity.

Closest to the claimed technical solution is a device for cooling and / or for heat recovery known from the patent RU 2671766, comprising several heat exchanger modules made with the possibility of connecting, each containing one heat exchanger and connected to ensure that their heat exchangers operate in a parallel connection circuit, characterized in that that each heat exchanger module has a housing surrounding the heat exchanger, which has one inlet and one outlet for air on the end sides a, as a result of which each of the successive heat exchanger modules has two inlet and two air outlet openings, and the device contains a common supply air duct and a common exhaust air duct connected to the heat exchanger modules to ensure uniform and parallel supply of the inlet openings for air of successive exhaust heat exchanger modules from a common exhaust air duct, as well as uniform and parallel output Foot air from the air outlet openings for the successive heat exchanger modules in a common supply air duct. Several heat exchanger modules are configured to vertically stack over one another, preferably stackable. Air inlets and air outlets of successive heat exchanger modules are arranged one above the other, the heat exchanger modules having a common supply air duct and a common exhaust air duct.

The disadvantages of the known device are:

- the complexity of the design of the heat exchanger modules and its low efficiency;

- high requirements for the material used for the manufacture of modules.

The technical result of the claimed utility model is to simplify the design, increase its efficiency and reduce the stiffness requirements of the material used.

The technical result is achieved by the fact that in the element of the plate heat exchanger for supply and exhaust ventilation systems, including a housing and a set of heat exchange plates made with the possibility of installation in a stack, according to a utility model, two types of heat exchange plates with perimeter edges are used, the input and output slots of which are made in the form of cutouts in the end walls of the heat exchanger plates, while the first type of heat exchanger plates have an inlet air gap on the left side and an outlet slit on t the front part to the right, and for the heat exchange plates of the second type, the air inlet gap is made on the right side and the output gap on the left side, the heat exchange plates of the first and second type are stacked alternately, a blown stiffener is installed over each heat exchanger plate, which protects the device from collapse.

The proposed design, composed of two types of heat exchanger plates, makes it possible to create a predominantly countercurrent recuperator, because, after the flow enters the slit of the recuperator layer, it spreads throughout the layer, including going into the place behind the “half-overlap”, subsequently moving almost only longitudinally. Similarly, the outlet stream also at the outlet of the recuperator has only a small area with almost diagonal movement.

This allows you to create the proposed design of the recuperator in addition to the main section with countercurrent movement only small areas with cross movement, which increases its efficiency. The use of heat transfer plates with perimeter edges allows to exclude the use of modules difficult to manufacture, which greatly simplifies the design. At the same time, the use of plates with flanges in combination with stiffeners allows not to use metal or plastic, but to use a rigid polymer film, which reduces the requirements for the material used. In addition, the claimed utility model allows you to create a device of any desired value of efficiency, by connecting the devices in series with each other, increasing the efficiency coefficient of the recuperator to a suitable value. The device allows you to increase or decrease the throughput by increasing or decreasing the number of plates in the stack.

The essence of the claimed utility model is illustrated by the drawings:

In FIG. 1 shows a heat exchange plate of plates of the first kind.

In FIG. 2 shows a heat exchange plate of plates of the second kind.

In FIG. 3 shows the device in assembled form.

The device consists of plates of the first type 1, the entrance slit 2 for air is made on the end part on the left, and the exit slit 3 on the end part on the right, and for heat exchange plates of the second type 4, the entrance slit 5 for air is made on the end part on the right, and the exit slit 6 on the end part on the left, the heat transfer plates of the first 1 and second type 4 are stacked in a stack 7 in turn, a blowing stiffener (not shown) is installed on top of each heat transfer plate, which protects the device from collapse, the case is not shown in the drawing an.

Blown stiffeners protecting the device from collapsing can be made in the form of "rugs" of springs or double plastic nets with "columns" between the nets, or in the form of intermittent ribs, if the layers (heat-exchange plates) or stiffener elements of the recuperator become dirty or torn replace with new ones, as is done with dirty filters. At the same time, heat transfer plates made of a rigid polymer film are significantly lighter than elements of the same purpose from other materials, which makes it possible to increase their number without significantly increasing the weight of the entire structure. Maybe they can be installed at the top of the workshop instead of air ducts.

Claims (1)

An element of a plate heat exchanger for systems of supply and exhaust ventilation, including a housing and a set of heat exchange plates made with the possibility of installation in a stack, characterized in that two types of heat exchange plates with rims along the perimeter are used, the inlet and outlet slots of which are made in the form of cutouts in the end rails heat-exchange plates, while in the heat-exchange plates of the first type, the inlet air gap is made on the end part on the left, and the outlet slit on the end part on the right, and in the heat-exchange plates orogo type air entrance slit is formed on an end portion on the right, and the output slot - on the left end portion, the heat transfer plates first and second types are stacked alternately on top of each heat transfer plate is installed purged stiffener that protects the device from collapsing.

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