RU2375640C2 - Equipment for heating and cooling of building rooms - Google Patents

Abstract

FIELD: heating. ^ SUBSTANCE: device for cooling and heating of building rooms is proposed. Its casing (14) is fitted by an inlet for circulating air and an outlet for the conditioned air. A heat exchanger unit (1) with a fan (4) is mounted in the casing; the fan (4) is set on the outlet heat exchanger side (1) and a condensate collecting tank (2) is set below the heat transferring surface of the heat exchanger (1). The heat transferring surface of the heat exchanger (1) on both ends is tightly enclosed by a casing (14) fitted by a tightly closed cover (7). The heat transferring surface of the heat exchanger (1) is made as a ring section in the form of a cylinder with its axis being perpendicular to the direction of the horizontal flow of incoming circulating air and the cylinder open part along its total height is closely attaching to the vertical closing wall of the casing (14). A suction fan (4) is mounted in the inside of the said cylindrical heat transferring surface; the fan outlet is passing with a seal through the casing (14) vertical closing wall in the area of the open part of the heat exchanger (1) heat transferring surface cylinder and is connected to an air distribution element (10) by means of a distributing air duct (9) through a diffuser (8). ^ EFFECT: reduced noise level. ^ 8 cl, 5 dwg

Description

FIELD OF THE INVENTION

The invention relates to a device for cooling and heating rooms in buildings.

State of the art

To ensure a comfortable atmosphere in administrative buildings, a fan heat exchanger has been known for a long time and is used as the final element of an air conditioning system that provides thermal comfort without the need for a direct supply of fresh air. At the same time, such an air conditioner is a counterbalance to radiator-type devices, offering instead of this final air conditioning device a rather powerful and flexible device that is independent of the main air flow. A further goal of using a fan heat exchanger was to simplify the regulatory system for heating and cooling water, since an auxiliary fan was added to the system, which allows to increase the range of technical characteristics by ensuring air circulation near the heat transfer surface. Thus, the possibility of heating and cooling was provided without strict dependence on direct air supply, which also resulted in the possibility of reducing the diameters of the central vertical air distribution pipe of high-rise buildings. Fan heat exchangers today are mainly used as the final elements of comfortable air conditioning in hotel rooms and meeting rooms, in administrative and commercial premises, etc., as well as to relieve temperature load in some production processes. Designs of such devices, for example, are described in US patent No. 4527762, 4548050, 4856672, 4986087, 5042269, 5071027, 5113667, 5131560, 5152154, 5174467, 5195332, 5199276, 5205472, 6109044.

From the point of view of the general solution, there were no significant changes in the manufacture and design of fan heat exchangers, and their improvement mainly consisted in the use of modern production equipment, including mass production, improving the ability to regulate their work, reducing their size, and, in part, increasing the efficiency of individual nodes, in addition to this, noise reduction in these devices was achieved by reducing their size and increasing fan speed. The initial result of the design of these air conditioning systems was that the noise did not steadily decrease where they were used. The noise of the air conditioner is the most problematic related circumstance. Initially caused by the rotation of the fan, the noise depends on the method of manufacturing the air conditioner, its heating and cooling power, and the place of use. Noise is mainly caused by an unsuccessful design of the device, for example, an erroneous design of the fan blades creates turbulence, or there are sharp angles when changing the direction of air flow, etc. Further, it is caused by an unsuccessful technical design of the device and its parts, which exposes the fan to excessive total load. Pressure losses are so large that to overcome them requires a high speed of rotation of the fan wheel and increase its useful work. In general, the fan noise is in a certain mathematical relation to its useful work and efficiency. In general, the principle that, with proper technical performance, the greater the number of revolutions of the fan, the greater the noise. The pressure loss on the parts and parts of the air conditioner, which must be compensated by the pressure from the fan, is equal to the square of the air flow rate through this segment. In practice, this means that if the air flow rate is reduced by half in key areas experiencing significant pressure loss, then this pressure loss will decrease by a quarter, and the required useful fan operation will be reduced to 25% of the originally required energy. True, the noise level will not be reduced in such a proportion, since the decrease in noise is determined by the logarithmic function, however, this decrease will be significant.

Disclosure of invention

The objective of the invention is to provide a device for cooling and heating rooms in buildings, characterized by reduced noise, simplified material and technical support, in other words, reducing the required number of parts and materials supplied, simplifying delivery and maintenance, and increasing mass production.

The invention provides a device for cooling and heating rooms in buildings, in the case of which, equipped with an inlet for circulating air and an outlet for conditioned air, a heat exchanger assembly with a fan is installed, the fan being located on the output side of the heat exchanger, and a condensate collecting tank is installed under the heat transfer surface of the heat exchanger while the heat transfer surface of the heat exchanger is tightly closed at both ends by a housing provided with a tightly fitting cover to ensure maintenance maintenance. The essence of the invention lies in the fact that the heat transfer surface of the heat exchanger is an annular section in the form of a cylinder, the axis of which is perpendicular to the direction of the horizontal flow of incoming circulating air, and the open part of the cylinder fits snugly over its entire height to the vertical closing wall of the housing, and inside the specified cylindrical heat transfer surface there is a suction fan, the outlet of which passes with a seal through the vertical closing wall of the housing and in open part of the cylinder of the heat transfer surfaces of the heat exchanger and is connected by a distribution duct to the air through the diffuser element.

At the inlet to the heat exchanger of the air to be conditioned, a mud filter can be installed, the shape of which corresponds to the inlet part of the heat exchanger. The distribution element is selected from the group consisting of anemostats, openings, wide ventilation outlets.

The device according to the present invention is compact and has standard external dimensions corresponding to the dimensions of the systems available in the ceilings or floors of buildings, for example, 60 × 60 cm. The aim is to manufacture modular equipment, which allows mass production with simplification of logistics, in other words, reduction of the required number of parts and materials supplied, simplification of delivery and maintenance. A further advantage is the reduction in noise level of equipment.

The heat exchanger tube at the inlet and outlet is connected to a four-pipe system for distributing the working medium, and all the supply and exhaust pipes for the cooling and heating working medium have interconnected shut-off valves that prevent the cooling and heating working medium from being supplied and removed from the heat exchanger, and in the supply pipes individual cooling valves are installed for the cooling and heating medium towards the heat exchanger, the outlets of which are connected to the pipe at the inlet of the heat exchanger ika, while the outputs of the shutoff valves towards the heat exchanger are connected to the pipe at the outlet of the heat exchanger. The control valves that control the flow of the cooling and heating medium are individually connected via a regulator to a room temperature sensor in the air-conditioned zone. At least one additional heat exchanger assembly with a fan, a distribution duct and an air distribution element is provided, which can be connected in parallel to the pipe at the inlet and to the pipe at the outlet of the heat exchanger. From the point of view of regulation, it is preferable if a single room temperature sensor installed in the room with the largest area or in such a room where there is the greatest heat loss or temperature increase controls more than one unit of the device.

A distribution duct leading from a heat exchanger assembly with a fan may include a duct for supplying fresh air from a central outdoor air processing station to circulate air in an air-conditioned room that is connected in the direction of the circulating air flow. In this way, an injection effect is achieved that helps the movement of air, and without reducing the return on the device. Shut-off valves, control valves and additional components of electrical equipment can be installed in the device. All this increases the compactness of the device.

Brief Description of the Drawings

The invention is further illustrated by the accompanying drawings and the following description of a specific example of one possible embodiment.

Figure 1 is a side view of a partial section of a horizontal ceiling version of an air conditioning device.

Figure 2 is a horizontal projection of the variant of Figure 1.

Figure 3 schematically depicts a system of more than one air-conditioning device, consisting of a master device and a dependent device connected to it, and the outlets of both devices through individual distribution pipes are connected to the corresponding distribution elements, in this embodiment being anemostats. The four-pipe system for distributing the working medium leads to the heat exchanger of the master device with which it is connected by means of the corresponding shut-off and control valves of the two-pipe connection. An additional, parallel connected dependent air conditioning device is connected to this two-pipe connection by means of a two-pipe system for distributing the working medium.

Figure 4 shows the connection of the four-pipe system for distributing the working medium with the master device.

Figure 5 shows a side view in partial section, as well as a horizontal projection of the distribution element, in this case being an anemostat.

The implementation of the invention

A device for cooling and heating (hereinafter referred to as air conditioning device) comprises a multi-plate heat exchanger 1 with a large area for air flow with a flow rate of about 400 m ³ / h and with a frontal flow area of about 0.2 m ² . The heat exchanger 1, with a height of about 220 to 250 mm, is three-row (it can also be two- or four-row) and contains 3 rows of copper tubes with a diameter of 0.8 to 1.2 cm, on which are stepped elongated elongated fins made of aluminum alloy, densely adjacent to the surfaces of copper tubes. One of these rows can be used for independent connection to a heating distribution system, the remaining rows can be connected to a cooling water distribution system. The heat exchanger is installed, together with the fan 4, in the housing 14 of the air conditioning device having an inlet for intake of circulating air and an outlet for conditioned air. The fan 4 is located on the output side of the heat exchanger 1, and under the heat transfer surface of the heat exchanger 1 there is a condensate collection tank 2. The heat transfer surface of the heat exchanger 1 is tightly closed at both ends by a housing 14 having a tightly fitting cover 7, providing access for maintenance. The heat transfer surface of the heat exchanger 1 is an annular section in the form of a cylinder, the axis of which is perpendicular to the horizontal flow of incoming circulating air, and the open part of the cylinder fits tightly over its entire height to the vertical closing wall of the casing 14. Inside this cylindrical heat transfer surface there is a suction fan 4, exhaust which passes with a seal through the vertical closing wall of the housing 14 in the area of the open part of the cylinder heat transfer the surface of the heat exchanger 1 and is connected through the diffuser 8 through the distribution duct 9 to the air distribution element 10. An additional condensate collection tank in communication with the condensate discharge opening may be connected to the condensate collection tank 2 in the form of an annular section located under the corresponding shape the heat transfer surface of the heat exchanger 1. At the inlet to the heat exchanger 1 of the air intended for conditioning, there is a mud filter 3, of the form which corresponds to that entry part of the heat exchanger 1.

In the interior space defined in this embodiment of the invention by the heat exchanger 1, there is a radial fan 4 in a spiral housing 5, a so-called two-way suction fan, capable of sucking air from both sides of the spiral housing 5. Alternatively, a diagonal fan (not shown) can be used. The fan wheel 4 is driven by an asynchronous electric motor 6, with the possibility of multi-stage or continuous speed control. This unit (heat exchanger 1, fan 4) is located in a sealed enclosure 14, so that the air sucked in by fan 4 does not extend beyond the heat exchange surface. The lower part of the housing 14 has a tightly fitting cover 7, which provides maintenance and cleaning of the fan 4 and the heat exchanger 1 from the inside. On the upper panel of the housing 14 there are latches for attaching the entire device to a horizontal building structure (for example, to the ceiling of a room). Alternatively, the casing 14 is attached by lower latches to the floor of the building, in which case the lid 7 is located in the upper part of the casing 14.

The fan 4 pumps air through a diffuser 8 into a distribution duct 9, which delivers air to the distribution element 10, for example, to an anemostat, an opening, a large area ventilation outlet. The purpose of the diffuser 8 is to reduce the flow rate of the air leaving the fan 4, and thereby reduce the pressure loss in the connected distribution duct 9. Between the distribution duct 9 and the outlet of the diffuser 8 there may be a flexible element, for example, a flexible pipe or fabric insert, which limits the transmission of vibration from the air conditioning device to the distribution duct 9 having a diameter of 250 mm Part of the diffuser 8 is a transition collar, providing a simple connection with a flexible element or with a distribution duct 9 of the desired diameter. The air-conditioning device has standard external dimensions corresponding to the systems existing in the ceilings or floors of buildings, for example, 60 × 60 cm. The goal is to produce a modular air conditioning device that allows mass production with simplification of material and technical support, in other words, reducing the required number of parts and supplied materials, simplification of delivery and maintenance.

Part of the electrical connection of the device and even the control of the device, the so-called electrical equipment, in addition, the space for arranging the inlets and outlets of the heat exchanger 1 can be part of the air conditioning device according to the present invention, which is its advantage. These parts fit snugly on the diffuser 8 at the output of the device. The heat exchanger tube 1 is connected to the pipes for supplying and discharging a working medium, for example, water, a mixture of antifreeze, etc. The connection of the tube of the heat exchanger 1 to the four-pipe system for distributing the working medium is made in such a way that the supply and outlet pipes for the cooling and heating medium are equipped with individual shut-off valves 11 that impede the simultaneous supply and removal of cooling and heating medium from the heat exchanger 1. They can be interconnected electrically with independent control elements or mechanically connected. In the operating mode of heating, the on-off shut-off valve of the hot water circuit first opens. This two-position shut-off valve is connected to the shut-off valve 11 of the cooling water circuit, which is simultaneously closed during the operating mode of heating. This occurs similarly to the opposite sequence of operation of two shut-off valves 11 during the operating cooling mode.

Direct control of the heating and cooling operation of the heat exchanger 1 is carried out using direct-acting control valves or two-way control valves 12, equipped with, for example, thermal heads or actuating mechanisms connected via a controller to a room temperature sensor 13 in an air-conditioned zone. The control valves 12 control the flow of the heating or cooling medium in accordance with the required temperature in the air-conditioned zone.

If the cooling working medium has temperature parameters of 14-18 ° С (inlet-outlet), heating water is -35-30 ° С (inlet-outlet), and the set parameters in the air-conditioned zone are 22 ° С for winter and 24.5 ° С for summer, the air conditioning unit will have a cooling or heating capacity of about 1.2 kW under standard office conditions, for example, with a useful area of 10-15 m ² . For offices with a larger area, additional air conditioning units should be added. In this case, from a control point of view, it will be convenient if several devices are controlled by a single room temperature sensor 13. According to the present invention, a single room temperature sensor 13 can control an air conditioning control device, i.e. a so-called master device equipped with a set of the above-described valves (shut-off valves 11 and direct-acting control valves 12), so that after direct-acting control valves 12 located in the direction of the conditioning device, the branches of the two-pipe connection individually go from the inlets and outlets of the heat exchanger 1, which go in the direction of other (dependent) air conditioning devices connected in parallel to the main device. If a single distribution element 10 is used both for supplying fresh air from a central outdoor air processing station and for supplying circulating air coming from an air conditioning device, then the external air supply must be provided so that the efficiency of the air conditioning device does not decrease, i.e. . external air should be introduced in the direction of the flow of circulating air, which creates an injection effect and helps the movement of air.

The solution in accordance with the present invention in no way reduces the floor space available to the tenant or user of the premises. It is very flexible and, from the point of view of architecture, allows to achieve a variety of interior solutions by a suitable choice of an air distribution element. The advantage is to reduce the need to restrict the air flow through the fan heat exchanger, as a result of which the deterioration in the heating and cooling ability due to clogging of the filter is largely avoided. A further advantage is that the supply of fresh air and circulating air from the fan heat exchanger can be directed to the same distributor. With the correct supply of fresh air by using the inductive effect, an increase in flow can be achieved (hence, an increase in heating and cooling efficiency). By installing several nodes next to each other, the desired introduction of heat or cold into an area with a large interior depth can be achieved.

The invention can be used for cooling and heating rooms in buildings.

Designations: 1 - heat exchanger; 2 - a reservoir for collecting condensate; 3 - filter; 4 - fan; 5 - spiral fan housing; 6 - fan electric motor; 7 - housing cover; 8 - diffuser; 9 - distribution duct; 10 - air distribution element; 11 - shutoff valves; 12 - control valves; 13 - room temperature sensor; 14 - case.

Claims (8)

1. A device for cooling and heating rooms in buildings, in the housing (14) of which, equipped with an inlet for circulating air and an outlet for air conditioning, a heat exchanger assembly (1) with a fan (4) is installed, and the fan (4) is located on the output side heat exchanger (1), and a condensate collection tank (2) is installed under the heat transfer surface of the heat exchanger (1), while the heat transfer surface of the heat exchanger (1) is tightly closed at both ends by a housing (14) equipped with a tightly fitting cover (7) to ensure maintenance, characterized in that the heat transfer surface of the heat exchanger (1) is an annular section in the form of a cylinder, the axis of which is perpendicular to the horizontal flow of incoming circulating air, and the open part of the cylinder fits tightly over its entire height to the vertical closing wall of the housing (14) moreover, inside the specified cylindrical heat transfer surface there is a suction fan (4), the exhaust of which passes through the seal with a vertical seal the wall of the housing (14) in the region of the open part of the cylinder of the heat transfer surface of the heat exchanger (1) and is connected via a distribution duct (9) through a diffuser (8) to an air distribution element (10). 2. The device according to claim 1, characterized in that at the inlet to the heat exchanger (1) of the air to be conditioned, a mud filter (3) is installed, the shape of which corresponds to the inlet part of the heat exchanger (1). 3. The device according to claim 1 or 2, characterized in that the tube of the heat exchanger (1) at the inlet and outlet is connected to a four-pipe distribution system of the working medium, and all the supply and exhaust pipes for the cooling and heating working medium have interlocking valves ( 11) that impede the simultaneous supply and removal of cooling and heating medium from the heat exchanger (1), and individual control valves are installed in the supply pipes for the cooling and heating medium towards the heat exchanger (1) ( 12), the outputs of which are connected to the pipe at the inlet of the heat exchanger (1), while the outputs of the shut-off valves (11) towards the heat exchanger (1) are connected to the pipe at the outlet of the heat exchanger (1). 4. The device according to claim 3, characterized in that the control valves (12) that control the flow of the cooling and heating medium are individually connected through the regulator to a room temperature sensor (13) in the air-conditioned zone. 5. The device according to claim 1, characterized in that the distribution element (10) is selected from the group including anemostats, openings, wide ventilation outlets. 6. The device according to claim 3, characterized in that at least one additional node of the heat exchanger (1) is provided with a fan (4), a distribution duct (9) and an air distribution element (10), connected in parallel to the pipe at the inlet and to the pipe at the outlet of the heat exchanger (1). 7. The device according to claim 1, characterized in that the distribution duct (9) for circulating air in the air-conditioned room, leading from the heat exchanger assembly (1) with a fan (4), includes a duct for supplying fresh air from the central outdoor processing station air, which is connected in the direction of the flow of circulating air. 8. The device according to claim 3, characterized in that the shut-off valves (11), control valves (12) and additional electrical components are installed in the device body.

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