CZ2007100A3 - Device for cooling and heating rooms in building objects - Google Patents

Abstract

The device for cooling and heating the space in the building objects comprises a housing (14) in which a heat exchanger unit (1) with a fan (4) is arranged, where the fan is located on the outlet side of the heat exchanger and its exhaust is through the diffuser (8) connected by a manifold (9) to an air distribution element (10), wherein the heat exchange heat exchanger is in the form of a cylindrical annular segment with an axis perpendicular to the flow direction of the circulating air supplied horizontally.

Description

Technical field

BACKGROUND OF THE INVENTION The present invention relates to an apparatus for cooling and heating rooms in buildings.

BACKGROUND OF THE INVENTION

To ensure a comfortable environment for office buildings, a fan convector, the so-called fancoil, has been known and used as the air conditioning end element for a long time, ensuring thermal comfort without the need for primary fresh air. It was created in parallel as an equilibrium of induction units, where the effort was to replace this air conditioning terminal element with a sufficiently powerful and flexible unit that would not be dependent on the primary air flow. At the same time, its purpose was to simplify the control of the heating and cooling water side by introducing an auxiliary fan into the system, which allowed a larger output range due to the air flow through the heat exchange surfaces. The heating and cooling capacity was thus determined without direct dependence on the primary air supply, which also meant a reduction in the cross-sections of the central vertical air distribution systems in high-rise buildings. Fan convectors as an end element of comfortable air conditioning are currently used mainly for air-conditioning of hotel rooms, common areas, administrative areas, shopping areas, etc., as well as for the removal of heat loads of some technological operations. The designs of these fan convectors are described, for example, in U.S. Patent Nos. 4,527,762,4548050,

4856672, 4986087, 5042269, 5071027, 5113667, 5131560, 5152154, 5174467, 5195332, 5199276, 5205472, 6109044.

In terms of overall design, the design and concept of the fan convectors did not change much, their development focused mainly on the use of modern production technologies with regard to series production, the possibility of improved regulation, reduction of its dimensions and partial efficiency. associated with reducing and also increasing the fan speed. The accompanying phenomenon in the use and design of air conditioning systems was that noise was not consistently reduced in these areas. The noise of the fan convector, which is mainly caused by the operation of the fan, is the most problematic "parasitic" quantity, which is influenced by the design of this unit, its heating and cooling outputs and the area of use. Noise is generally caused by improperly designed unit design, where turbulent flow occurs due to improper fan impeller blades design, sharp edges in the air flow direction, etc. In addition, unsuitable technical design of the unit and its accessories requiring high total fan pressure. Pressure Loss * «« * * * * * *

• * »fan size is large enough to require high impeller speed and increased fan power to overcome it. Fan noise generally has some mathematical dependence on fan power and efficiency. As a general rule, if the fan is of good technological design, the higher the fan speed, the higher the noise. The pressure drop of the elements in the fan convector and its accessories, which the fan pressure must overcome, is in relation to the air flow velocity of this segment in the square of the square. In practice, this means that if key air pressure components are reduced by half in the key components with high pressure drop, the pressure drop will be reduced by a quarter and the theoretical fan input required will be reduced to 25% of the original energy requirement. Although noise will not be reduced in this ratio because noise reduction will have a logarithmic dependence, but still noise reduction will be significant. SUMMARY OF THE INVENTION The object of the present invention is to provide a device for cooling and heating spaces in building objects with reduced noise, with simplified logistics, i.e. by reducing the number of parts, its inventory, simplifying shipping and servicing, and increasing serial production.

SUMMARY OF THE INVENTION

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a device for cooling and heating rooms in a building, in the housing of which is provided with an inlet for the intake of circulated air and treated air. the heat exchanger surface of the heat exchanger is a condensate tray, and wherein the heat exchanger surface of the heat exchanger is sealed at both ends by a housing having a sealed service lid. SUMMARY OF THE INVENTION The heat exchanger surface of the heat exchanger is in the form of a cylindrical annular segment with an axis perpendicular to the direction of flow of the horizontally supplied recirculating air, and with its closed portion of the cylinder sealed over the height of the seal. is a suction blower whose exhaust is sealed through the vertical enclosure wall of the housing at the unclosed part of the cylinder of the heat exchanger heat exchanger surface, and is connected via a diffuser to the air distribution element via a diffuser.

At the inlet of the heat-treated air of the heat exchanger a dirt filter can be fitted, the shape of which corresponds to this inlet part of the heat exchanger. The distribution element is selected from the group consisting of an diffuser, slot, large diffuser.

The device according to the invention is compact and has standardized external dimensions which correspond to existing soffit or floor systems of building objects, for example 60 x 60 cm. The idea is to achieve the modularity of the equipment that enables serial production, simplifies logistics, that is, reduces the number of parts, their inventory, simplifies shipping and service, Another advantage is the reduction of equipment noise.

The heat exchanger tube is connected at its inlet and outlet to the four-pipe working medium so that all the cooling and heating working medium supply and exhaust pipes are individually provided with mutually coupled shut-off valves to prevent simultaneous inlet and outlet of the heating and cooling working medium to the heat exchanger. control valves, the outlets of which are connected to the pipe at the inlet of the heat exchanger, and the outlets of the shut-off valves in the direction of the heat exchanger, are connected to the pipe at the outlet heat exchanger.

The control valves for flow control of the heating and cooling medium are individually connected via the controller to the room temperature sensor in the air-conditioned room.

At least one additional heat exchanger unit with fan, manifold and air distribution element may be connected in parallel to the inlet pipe and the outlet pipe. From the control point of view, it is advantageous that a single room temperature sensor controls multiple units of the device in a single room of larger dimensions or greater heat loss respectively. heat gains.

The circulation air duct in the air-conditioned space from the heat exchanger unit with a fan can be connected to the fresh air duct from the central outdoor air treatment plant so that it is connected in the direction of circulation air flow. In this way, an injection-promoting effect is created to aid the flow of air, while the performance of the device is not reduced. Individual shut-off valves and control valves as well as wiring elements can be provided in the housing of the device according to the invention. All this contributes to the compactness of the device.

Overview of the drawings

The invention will be further elucidated by way of a specific example of one of its possible embodiments, by means of the accompanying drawings and the following description of an example of a particular embodiment. Fig. 1 is a side elevational view in partial vertical section of an exemplary embodiment of an air conditioning unit in a horizontal inter-ceiling design; Fig. 2 is a plan view of the embodiment of Fig. 1. FIG. 3 shows schematically an assembly of a master air conditioning unit with a slave air conditioning unit connected thereto, where the outlets of both units are connected via respective manifolds to the corresponding distribution elements, which in the example are made by diffusers. A four-pipe piping of the working medium is connected to the master unit, followed by a two-pipe connection to the heat exchanger of the master unit behind the respective shut-off and control valves. Another slave air-conditioning unit is connected in parallel to this two-pipe connection via a two-pipe distribution of the working medium. The connection of the four-pipe working medium to the master air-conditioning unit is shown in Fig. 4. Fig. 5 is a side elevational view in partial vertical section, giving a plan view of the distribution element formed by the diffuser in this embodiment.

DETAILED DESCRIPTION OF THE INVENTION

The cooling and heating installation (hereinafter referred to as the "air-conditioning unit") consists of a large surface heat exchanger χ for an air flow of approximately 400 m ³ / h and a front flow area of approximately 0,2 m ² in a three-row design (may be two to four rows), it comprises three rows of copper tubes with a diameter of 0.8 to 1.2 cm, on which spaced rectangular aluminum alloy lamellae are threaded apart, which closely adhere to the surface of the copper tubes. One of these series can be used for separate connection to the heating system, the remaining series can be connected to the cooling water system. It is, together with the fan 4, arranged in the housing 14 of the air-conditioning unit, provided with an inlet for the intake of the circulating air supply and the exhaust of the conditioned air. A fan 4 is provided on the outlet side of the heat exchanger X, below the heat exchanger surface X of the heat exchanger X is a condensate tray 2. The heat exchanger surface χ of the heat exchanger χ is sealed at both ends by a housing 14. it is in the form of a cylindrical annular segment with an axis perpendicular to the direction of flow of horizontally supplied recirculating air, and with its unclosed portion of the cylinder over the full height sealed adjacent to the vertical closure wall of the housing 14. Inside this cylindrical heat transfer surface is a suction fan 4 whose exhaust is sealed through the vertical closure through the wall of the housing 14 at the position of the non-closed part of the cylinder of the heat exchange surface of the heat exchanger 1, and is connected via a diffuser 8 to the air distribution element 10 via a manifold 9. An annular segment shaped condensate tray 2 located below the corresponding heat exchange surface of the heat exchanger X can be followed by an additional condensate tray connected to the condenser drain.

At the inlet of the heat-treated air of the heat exchanger 1, a dirt filter 3 is provided whose shape corresponds to this inlet part of the heat exchanger X.

In the interior defined by this heat exchanger X in the described embodiment, a radial fan 4 is located in the spiral housing 5, with the possibility of sucking in air from both sides of the spiral housing 5, so-called double-sided suction fan. Alternatively, you may want to use the * * ♦ · · · · · · · · · · · · · · · · ·

Μ · diagonal fan (not shown) can be used. The fan impeller 4 is driven by an asynchronous electric motor 6 with the possibility of multi-stage or stepless speed control. This assembly (heat exchanger 1, fan 4) is located in a sealed housing 14 so as to prevent air flow that sucks the fan 4 away from the heat exchanger surfaces. The lower part of the housing 14 is provided with a sealed service cover 7 to allow maintenance and cleaning of the fan 4 and the heat exchanger 1 from the inside thereof. The housing 14 is provided with mountings on its top plate for attaching the entire device to a horizontal building structure (e.g., room ceiling). Alternatively, the housing 14 is attached to the floor of the building by lower anchors, in which case the service cover 7 is at the top of the housing 14,

The blower 4 blows air through the diffuser 8 into the manifold 9, which supplies air to the distribution element 10, for example an anemostat, slot, large-area diffuser. The purpose of the diffuser 8 is to reduce the speed of the air exiting the fan 4 and thereby reduce the pressure loss in the connected manifold 9. Between the manifold 9 and the outlet of diffuser B there may be a flexible element such as a flexible pipe or textile insert. device respectively. The diffuser 8 has a transition collar, which allows easy connection to a flexible element or to a distribution pipe 9 of suitable cross-section. The air conditioner has standardized external dimensions that correspond to existing soffit or floor systems, for example 60 x 60 cm. The idea is to achieve the modularity of the air-conditioning unit, which allows serial production, simplification of logistics, ie reduction of the number of parts, their stock, simplification of shipping and service.

The air conditioning unit according to the invention may advantageously comprise a part of the electrical connection of the unit, possibly also its regulation, the so-called electric box, and furthermore a space for the location of the valves of the heat exchanger 1. These parts abut the diffuser 8 at the outlet of the unit. The heat exchanger tube 1 is connected to the inlet and outlet of the working medium, eg water, antifreeze, etc. The connection of the heat exchanger tube 7 to the four-pipe distribution of the working medium is carried out in such a way that provided with shut-off valves 11 so as to prevent simultaneous inlet and outlet of heating and cooling medium to the heat exchanger 1. They can be electrically coupled with separate actuators, or they can be mechanically coupled. In the heating mode, the two-position shut-off valve J1 on the heating water circuit is first opened, which is coupled with the shut-off valve J1 on the cooling water circuit. heating closes. Analogously, this is the opposite of the two of these shut-off valves 11 in the cooling operation mode.

· · · * * * * * * *

The regulation of the heating and cooling capacity of the exchanger and heat is carried out by means of direct resp. two-way control valves 12, provided, for example, with a thermo-heater or actuators, which are connected via a regulator to a room temperature sensor 13 in an air-conditioned space. The control valves 12 regulate the flow of heating and cooling medium corresponding to the desired temperature in the air-conditioned space.

If the coolant has temperature parameters of 14 ° C / 18 ° C (inlet / outlet) and heating water 35 ° C / 30 ° C (inlet / outlet), the air conditioner will have 22 ° C in winter and 5 ° C in summer cooling resp. heating capacity of approximately 1.2 kW, which corresponds, for example, in normal office space of 10 to 15 m ^{2 of} usable area. In the event that these offices have a larger area, it is necessary to place in this space wolf air conditioners. From the control point of view, it is advantageous for several units to be controlled by one room temperature sensor 13. According to the present invention, one control air conditioning unit, the so-called master, can be controlled by one room temperature sensor 13, which is then equipped with the above-described valve series (shut-off valves 11 and direct control valves 12). to the air-conditioning unit, on the inlet and outlet of the heat exchanger 1, the taps are already made individually on a two-pipe connection, which is then directed to other air-conditioning units (slaves) connected in parallel to the master. If one distribution element 10 is used to supply fresh air from the central outdoor air treatment plant and the circulating air from the air conditioning unit, it is necessary that the outdoor air supply is designed so that it does not reduce the air conditioning unit's performance and is directed downstream. thus creating an injection effect to assist the air flow.

The solution according to the invention does not in any way reduce the floor area of the leasable space. It is very flexible and allows to create various interior solutions by architectural design. The advantage is less dependence on the reduction of the air flow through the fan convector and thus the heating and cooling capacity when the Filter is clogged, as well as the possibility to place the supply of fresh air and circulation air from the fan convector into one element. If the fresh air supply is connected properly, the induction effect increases the air flow (and thus the heating and cooling capacity). In areas with a large internal depth, targeted zone heat and cold supply over the entire area can be achieved by placing multiple units in a row.

Industrial applicability

The invention is applicable to the cooling and heating of premises in buildings.

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Claims (8)

PATENT CLAIMS An apparatus for cooling and heating a space in a building, in the housing (14) of which is provided with an inlet for the intake of the circulating air supply and the treated air exhaust, there is a heat exchanger unit (1) with a fan (4); ) is arranged on the outlet side of the heat exchanger (1), wherein a condensate tray (2) is located below the heat exchanger surface of the heat exchanger (1), and wherein the heat exchanger surface of the heat exchanger (1) is sealed at both ends by a casing (14) a service wolf (7), characterized in that the heat exchanger surface of the heat exchanger (1) is in the form of a cylindrical annular segment with an axis perpendicular to the direction of flow of horizontally supplied circulating air; (14), and wherein there is a suction valve within said cylindrical heat transfer surface The exhaust (4), the exhaust of which is sealed through the vertical closure wall of the housing (14) at the non-closed part of the cylinder of the heat exchange surface of the heat exchanger (1) and connected via a diffuser (8) to the air distribution element (10). Device according to claim 1, characterized in that a dirt filter (3) is provided at the inlet of the heat-treated air of the heat exchanger (1), the shape of which corresponds to this inlet part of the heat exchanger (1), Device according to claim 1 or 2, characterized in that the heat exchanger tube (1) is connected at its inlet and at its outlet to a four-pipe distribution of the working medium so that all the inlet and outlet pipes of the cooling and heating working medium are individually provided mutually coupled shut-off valves (11) to prevent simultaneous inlet and outlet of heating and cooling working medium to the heat exchanger (1), behind which control valves (12) are individually arranged in the supply pipes of heating and cooling working medium towards the heat exchanger (1) ), the outlets of which are connected to the tube at the inlet of the heat exchanger (1) and at the same time the outlets of the shut-off valves (11) in the direction of the heat exchanger (1) are connected to the tube at the outlet of the heat exchanger (1). Device according to claim 3, characterized in that the control valves (12) for controlling the flow of heating and cooling working medium are individually connected via a controller to a room temperature sensor (13) in the air-conditioned space. Apparatus according to any one of claims 1 to 4, characterized in that the distribution element (10) is selected from the group consisting of an diffuser, a slot, a large-area diffuser. · ·.. •................ Device according to one of Claims 3 to 5, characterized in that at least one further heat exchanger unit (1) with a fan (4), a manifold (9) is connected in parallel to the inlet pipe and the outlet pipe of the heat exchanger (1). ) and an air distribution element (10). Device according to one of Claims 1 to 6, characterized in that a fresh air supply pipe from a central outdoor air treatment plant is connected to the circulation air duct (9) in the air-conditioned space from the heat exchanger unit (1) with a fan (4). so that it is connected in the direction of circulation of the circulating air. Device according to one of Claims 3 to 7, characterized in that individual shut-off valves (11) and control valves (12) and wiring elements are arranged in its housing. (tlk (i /: ί '/ / γ,. · · »» • * * * * 1 & ο «C-