UA71959U - Device for energy-saving ventilation - Google Patents

Abstract

A device for energy-saving ventilation has a ventilation pipe, recuperative surface heat exchanger with opposite directed intake and exhaust channels, two fans for simultaneous separate ventilating those channels. The heat exchanger is built-in to inside of ventilation pipe and has parallel to its geometrical axis, separated with long plates that alternate intake and exhaust channels. The end sections of ventilation pipe are closed with air-distribution grates.

Description

The useful model belongs to the design of devices for decentralized energy-saving ventilation of residential, public and industrial premises, which, as a rule, are equipped with air conditioners.

Free ventilation of such premises through windows or transoms leads to loss of heat spent on heating in winter, and to an increase in energy costs for air cooling in summer. Energy losses are greater, the larger the volume of the ventilated room, the temperature difference outside and inside it, and the given frequency of air exchange.

To reduce losses, devices for forced ventilation are used, which heat or cool the supply of fresh air to the room by recuperative heat exchange with the air emitted into the atmosphere.

The first samples of such devices were expensive to manufacture and inefficient in operation. However, the increase in demand stimulated their rapid improvement.

Known from the description to OA 11134 ) a device for energy-saving ventilation, which has: (1) a flowing hollow body, equipped on one side with a pair of nozzles for communication with the atmosphere and on the other side with a pair of nozzles for communication with the ventilated room; (2) a shell-and-tube heat exchanger, the tube boards of which serve as hermetic partitions and divide the body cavity into two chambers, which independently communicate with the atmosphere and the ventilated room, respectively, through the inter-tube space and through the pipes of this heat exchanger and through the mentioned nozzles, (3) two fans with counter-connected actuators that are built into the nozzles that serve to connect the flow case with the ventilated room.

The use of a shell-and-tube heat exchanger with a developed heat exchange surface significantly increased the thermal efficiency. device. However, such heat exchangers, firstly, have a high material capacity and, secondly, significantly increase the aerodynamic resistance to the flows of fresh and exhaust air. This forces each ventilation tract to be equipped with a sufficiently powerful fan. Not only that, the use of two pairs of nozzles in each of the air exchange paths complicates the installation of the known device.

A more convenient installation device for energy-saving ventilation, which is technically closest to the device offered below, is disclosed in the description of the utility model to OA 27057 |.

Zo It has: (1) a hollow polymer body, which includes a central ventilation pipe, the cavity of which is divided into exhaust and supply zones, and a shell covering the ventilation pipe with a radial gap; (2) a metal recuperative surface heat exchanger of the "pipe-in-pipe" type is built into the gap between the ventilation pipe and the casing, the oppositely oriented multiple curved supply and exhaust channels of which are independently connected to the indicated exhaust and supply zones of the ventilation pipe, and (3) as a rule, two fans for simultaneous separate purging of the specified channels of the recuperative heat exchanger.

The heat exchanger of the "pipe-in-pipe" type is also bulky and, in combination with the heat exchanger, significantly increases the material capacity of the known device. In addition, it has high aerodynamic resistance, which increases operational energy costs.

The useful model is based on the task of creating a less material-intensive and energy-consuming device for energy-saving ventilation by changing the design of the heat exchanger and its location relative to the ventilation pipe.

The problem is solved by the fact that in the device for energy-saving ventilation, which has a ventilation pipe, a recuperative surface heat exchanger connected to this pipe with counter-oriented supply and exhaust channels that communicate with the atmosphere and with the ventilated room, respectively, and two fans for simultaneous separate blowing of the specified channels, according to a useful model, the heat exchanger is built inside the ventilation pipe and has supply and exhaust channels parallel to its geometric axis, separated by alternating longitudinal plates, and the end parts of the ventilation pipe are covered with air distribution grids, the holes in which correspond to the profiles and location of the specified channels and open in one of these grates into the supply channels and in the second grate into the exhaust channels.

Plates of heat exchangers can be made of metal foil. The parallel supply and exhaust channels limited by such plates have negligible aerodynamic resistance to air flows. This dramatically reduces the material capacity of the device and energy consumption for its operation.

The first additional difference is that the heat exchanger has equidistantly located flat or arc-shaped longitudinal plates, alternating, and the supply and exhaust channels have the form of slits of equal width between the specified plates. Heat exchangers of this type are the easiest to manufacture.

A second additional difference is that a central rod is fixed inside the ventilation pipe, the heat exchanger has longitudinal plates, the profile of which is selected from the group consisting of a segment of a straight line, a broken line composed of at least two straight segments, and an arc of a curve of the second order, each such the plate is fixed with one end relative to the wall of the ventilation pipe, and with the other end - relative to the specified rod, and the alternate supply and exhaust channels have the form of sector slots between the specified plates. This allows you to constructively adjust the total surface area of the heat exchange depending on the specific heat load.

It is clear to a person skilled in the art that the specified additional differences can be used in various combinations with the main inventive idea and that other shapes of the profiles of the longitudinal plates and the intake and exhaust channels demarcated by them are possible.

The essence of the useful model is explained by a detailed description of the design and operation with references to the drawings, where in fig. 1 shows the general view of the simplest device for energy-saving ventilation of premises in a longitudinal section through the plane of symmetry; in fig. 2 - one of the possible variants of the decorative panel on the end part of the device, which is located inside the ventilated room (cross-section along AA from Fig. 1); in fig. C is the intersection

B-B from fig. 1, which shows the simplest version of the profile of inflow and exhaust channels, delimited by equidistantly located flat longitudinal plates; in fig. 4 - a more complex version of the profile of slit-like inflow and exhaust channels, separated by equidistantly located arc-shaped longitudinal plates; in fig. 5, 6 and 7 - variants of the profile of the supply and exhaust channels in the form of sector slots demarcated by longitudinal plates, each of which is fixed with one end relative to the wall of the ventilation pipe, and with the other end relative to the central rod inside this pipe (for cases when the profile of the plates has the form segment of a straight, broken line consisting of segments of straight lines and the arc of a curve of the second order); in fig. 8 - an example of the profile of the air distribution grids, which corresponds

With flat slit-like inflow and exhaust channels (view from the end); in fig. 9, 10, 11 and 12 - other possible variants of the profile of inflow and exhaust channels.

Detailed description of the utility model

In the general case, the proposed device (see Fig. 1) has a predominantly round cylindrical (usually polymer or heat-insulated metal) case in the form of a ventilation pipe 1. In the working position, this pipe 1 penetrates the wall of the house, which in Fig. 1 is conventionally indicated by two vertical dashed lines.

A recuperative surface heat exchanger is built into pipe 1. It has unmarked, especially oppositely oriented, alternating expiratory and expiratory ducts. They are separated by longitudinal plates 2 and communicate with the atmosphere and the ventilated room, respectively, through the end air distribution grids 3. The shapes and locations of the holes in these grids З correspond to the mentioned channels.

Fans 4 are installed in front of grilles C for simultaneous separate blowing of supply and exhaust channels.

In practice, to reduce noise, the fan 4, located on the side of the ventilated room (see Fig. 1 on the right), is inserted into the pipe 1. Its end, which protrudes for some distance inside the ventilated room, is usually covered with a decorative panel 5, which, usually, perforated at the level of fresh air release (see Fig. 2).

The design options of the device differ in the profiles and mutual location of the plates 2 and the corresponding profiles and mutual location of the supply and exhaust channels and holes in the air distribution grids 3.

Thus, Figures 3 and 4 show the simplest flat or arc-shaped slit-like intake and exhaust channels, which are delimited by equidistantly located flat or arc-shaped longitudinal plates 2. An example of the form of air distribution grilles 3, which corresponds to the profile and location of the openings of the channels from Fig. 3, shown in fig. 8.

Similarly, figures 5, 6 and 7 show variants of the profile of the channels in the form of sector slots demarcated by longitudinal plates, each of which is fixed at one end relative to the pipe wall 1, and at the other end relative to the central rod 5 inside it. The profile of the plates 2 shown in these figures is selected from the group consisting of a segment of a straight, broken line consisting of at least two straight segments and an arc of a curve of the second order. This significantly increases the specific area of the heat exchange surface per unit volume of the ventilation pipe 1. It is clear to a specialist that the profiles of the supply and exhaust channels and the corresponding plates 2 can have other shapes (see, for example, figures 9, 10, 11 and 12 ), that the inflow tract can be equipped with a suitable aerosol filter, an adsorber or absorber of harmful gaseous atmospheric pollutants, a means of humidification and/or aromatization of fresh air and other additional devices, and that the device can have an automated control system (for example, based on a programmable microcircuit) , which includes sensors of the actual air temperature inside and outside the ventilated room, an adjustable air temperature sensor inside this room, a comparator and a fan control unit 4.

The described device in any constructive variant works in the following way.

With the synchronous operation of the fans 4, the opposite flows of fresh and exhaust air (see arrows in Fig. 1) effectively exchange heat through thin plates 2 that separate the supply and exhaust channels. Manual or automatic adjustment of fan thrust 4 provides the desired air exchange rate.

Built into the ventilation pipe, a recuperative surface heat exchanger based on thin (in particular, made of aluminum or copper foil) longitudinal plates ensures intensive heat exchange even in a small volume. Today, high-precision laser cutting of blanks of such plates is not significantly time-consuming.

Therefore, the proposed device for energy-saving ventilation can be a mass-produced product.

Claims (4)

USEFUL MODEL FORMULA 1. A device for energy-saving ventilation, which has a ventilation pipe, connected to this pipe is a recuperative surface heat exchanger with oppositely oriented supply and exhaust channels, which communicate with the atmosphere and with the ventilated room, respectively, and two fans for simultaneous separate blowing of the specified channels, Zo which is distinguished by the fact that the heat exchanger is built into the ventilation pipe and has supply and exhaust channels parallel to its geometric axis separated by alternating longitudinal plates, and the end parts of the ventilation pipe are covered with air distribution grids, the holes in which correspond to the profiles and location of the specified channels and are open in one from these grids into the supply channels and in the second grid - into the exhaust channels. 2. The device according to claim 1, which is characterized by the fact that the heat exchanger has equidistantly located flat or arc-shaped longitudinal plates, alternating, and the supply and exhaust channels have the form of flat or curved slits of equal width between the specified plates. 3. The device according to claim 1, which is characterized by the fact that a central rod is fixed inside the ventilation pipe, the heat exchanger has longitudinal plates, the profile of which is selected from the group consisting of a segment of a straight, broken line composed of at least two straight segments, and an arc of a curve of the second order, each such plate is fixed with one end relative to the wall of the ventilation pipe, and with the other end - relative to the specified rod, and the alternate supply and exhaust channels have the form of sector slots between the specified plates. and I KE i xx d Kiyi a write I -kt hro hi Kk ' Fig. 1 re: ry 4 DK You You - ; neck Fig Fig. From her for Y I Vk: pc Mt mak I SHA vek and I WRITE - S Fig. 4 Fig. and Mesa is still in Sy VE. eh Fig. b Fig. 7 / En I would in xx Fig. 8 Fig. 9 th RA A AT" WE write OHMYNYa En MORE "Fig. 10 "Fig. 11th A EE S M IN Languages "Fig. 12