AT510142A1 - PLANT FOR AIR AND WATER HEATING - Google Patents

Description

CZ 21199 ul

Plant for air or water heating

Technology area

The technical solution concerns the plant areas for air or water heating with the use of solar energy.

Previous state of the art

So far, solar panels of various construction are mainly used for air or water heating with the use of solar energy.

The best known and simplest solar panels are provided by a sleeve textile, formed from both sides with a plastic covering pads, especially PVC, PU or derer copolymers, filled with water, forcibly or arbitrarily flow through the sleeves formed in the textile, and in this Flow it is heated by the influence of solar radiation. To the detriment of these solutions is a relatively low efficiency, because the warming of water, takes place only in the sunshine.

The other known solution are the so-called photovoltaic elements that use the sunshine for conversion to electrical energy and then following the heat energy to the detriment of these solutions is mainly a higher price in the installation and especially the need for connection to the electrical supply network in the case of using a larger system of these photovoltaic elements.

Also known are the solar panels formed by flat pressure or vacuum technical solar collectors. The heat insulation used in these systems is usually the vacuum which lies between the glass parts of the flat pressure collectors or between the tubes of the tubular vacuum collectors. More efficient tubular systems are used because of their low heat losses and also for their higher yield, because the heat can be obtained even in very low sunshine, as well as at low outdoor temperatures, even below 0 ° C. The basic panel of the tubular vacuum collectors is constituted by a system of double-faced vacuum glass tubes through which a metal tube is transferred to transfer the recovered heat, with its one side attached to the accumulation part of the panel, where the heat is transferred to a heat-conducting liquid and continues with this liquid Exchanger and transported further into the heating system.

Each of the chosen solutions has its specific properties which, in the specific case, favor it before other solutions, or vice versa, have their shortcomings limiting their use. Unfortunately, the complexity of most solutions seems to be a major drawback, as the collector systems must in most cases be supplemented by other regulatory and safety elements.

The basic element of the technical solution

The deficiencies mentioned are essentially eliminated by the plant for air and water heating, formed by the vortex tube, from the system of rod nozzles, the 4 ·· * * · · · · CZ 21199 Ul

System of the two-surface vacuum glass tubes, with an insulated hood for supporting the vortex tube and with an air pressure or pressurized water source according to this technical solution, the principle is that the vortex tube, conveniently formed with a tube made of the heat-conducting material, perpendicular and / or obliquely its elongated axis is connected to at least one row of bar nozzles, conveniently also made of a thermally conductive material ordered in one plane and at regular intervals, the vortex tube being placed in the space formed by an insulated hood and oriented horizontally or vertically, when the double-walled vacuum glass tubes with an open side are detachable into the interior of the insulated hood by means of the in the sheath of the insulated hood of the double-lined vacuum glass tubes coincident with oblong axes of these two-surface vacuum glass tubes Vortex tube made openings, and the other side of these two-layered vacuum glass tubes is hermetically closed when connected to one side of the vortex tube, the input for compressed air or pressurized water, and at the jj the other side of the vortex tube to its hood the output to dissipate the heated

Air or heated water is connected. The removal of the heated air is in! a favorable copy directly led out in the room to dehydration, or it is connected to another system for processing this heated air, with advantage it is connected in a circuit with the heat pump. The discharge of the heated water is led to the exchanger or boiler and further turned on in the desired circle of the warm water of the heating system, with advantage it is connected in a circuit with heat pump.

The system for air or water heating according to this technical solution allows to temper the particular room for further use or dry out or remove the warm water for further use. It is convenient to use the plant, especially in autumn and spring, when it is not necessary to exploit the full heating of the object and the heat obtained by the plant for air or water heating according to this technical solution reaches its temperature. Overview of the pictures in drawings

The technical solution is explained in more detail by means of drawings showing the system for air or water heating. FIGURE 1 shows the single-row system for air or water heating with double-surface vacuum glass tubes, which are set perpendicular to the vortex tube in the face view. FIGURE 2 shows the same system from the side view, FIGURE 3 shows the double-row system for heating water with double-surface vacuum glass tubes. Fig. 4 shows the single-row system for air or water heating with double-surface vacuum glass tubes, which are set obliquely to the vortex tube.

Examples of implementation

example 1

The installation for air heating according to FIG. 1 and FIG. 2 is formed with the vortex tube I for air distribution, oriented horizontally, perpendicular to the axis of the vortex tube 1. and in a plane at regular intervals a number of rod nozzles 3 is firmly connected, thus forming the vertically mounted rod nozzle system 3 for distributing the air intended for heating. Each of the bar nozzles 3 is applied in the double-surface vacuum glass tube 2 made of borosilicate glass, supplied with inner lining to increase the Sonnenwärmeabsorbierung. The rod nozzles 3 are applied in two-surface vacuum glass tubes 2 coinciding with elongated axes of these two-surface vacuum glass tubes 2_. The vortex tube 1 is placed in the insulated hood 4, to which also the system of the two-surface vacuum glass tubes 2 is detachably connected with its first open side. The other side of the two-surface vacuum glass tubes 2 is hermetically sealed. To one side of the vortex tube l the input 5 of the compressed air is connected, the source of which is a fan. As a source, for example, a compressor may also be used. This air is passed through the vortex tube and rod nozzles 3 in the two-surface vacuum glass tubes 2, where it comes to their heating. The heated air is then led into the hood 4 isolated from the insulated hood 4, the vortex tube i and the outlet 6 from the latter to the collection point for further processing of this heated air or directly into the heated space.

Example 2

The water heating system according to FIG. 1 and FIG. 2 is formed by the vortex tube i for the water distributor, oriented horizontally, to which perpendicular to the axis of the vortex tube \ and in a plane at regular intervals a row of bar nozzles 3 fixedly connected, thus laying vertically System of stick nozzles 3 for distributing the water intended for heating forms. Each of the bar nozzles 3 is placed in the double-surface vacuum glass tube 2 made of borosilicate glass, supplied with inner lining to increase the absorption of solar heat. The bar nozzles 3 are mounted in two-surface vacuum glass tubes 2 coinciding with elongated axes of these two-surface vacuum glass tubes 2. The vortex tube 1 is mounted in an insulated hood 4, where even with its first open side, the resulting system of the two-surface vacuum glass tubes 2 is connected. The other side of the two-surface vacuum glass tubes 2 is hermetically sealed. To one side of the vortex tube I, the input 5 is connected to pressurized water, the source of which is a pump. This water is passed through the vortex tube \ and the rod nozzles 3 in the two-layered vacuum glass tubes 2, where it comes to its heating. The heated water is then led out into the insulated hood 4 of the vortex tube 1 and fed through outlet 6 from this insulated hood 4 into the exchanger or boiler and further into the desired circuit of the warm water of the heating system or directly to the hot water consumer.

Example 3

The plant for air heating according to FIG 3 is formed with the vortex tube 1 for air distribution, oriented vertically to the perpendicular to the axis of the vortex tube 1 and in a plane at regular intervals two rows of rod nozzles 3 are firmly connected, so a horizontally mounted system of 3 stick nozzles for the distribution of air intended for heating form. Each of the bar nozzles 3 is mounted in a double-surface vacuum glass tube 2 made of borosilicate glass, supplied with inner coating to increase the absorption of solar heat. The rod nozzles 3 are mounted in en two-surface vacuum glass tubes 2 coincident with elongated axes of these two-surface vacuum glass tubes 2. 6 «· · * < *» · • ♦ · «• · · * *

CZ 21199 ul

The vortex tube I is mounted in an insulated hood 4, in which space the system of double-surface vacuum glass tubes 2 is also detachably connected with its first open side. The other side of the two-surface vacuum glass tubes 2 is hermetically sealed. To one side of the vortex tube! the input 5 of the compressed air, whose source is a fan, is connected. It is possible to use as source e.g. also to use a compressor. This air is through the vortex tube! and the bar nozzles 3 are guided in the two-surface vacuum glass tubes 2, where this heating comes. The heated air is then led out into the space formed by the insulated hood 4 and through the exit 6 from this hood 4 to a collection point for further processing of this heated air or directly into the heated space.

Example 4

The plant for water heating is according to FIG 3 through the vortex tube! formed for the distribution of water, oriented vertically to which are perpendicular to the axis of the vortex tube i and in a plane at regular intervals two rows of rod nozzles 3 are firmly connected, which is such a horizontally mounted system of rod nozzles 3 for distribution of water intended for heating form. Each of the bar nozzles 3 is mounted in a double-surface vacuum glass tube 2 made of borosilicate glass, supplied with inner coating to increase the absorption of solar heat. The rod nozzles 3 are mounted in two-surface vacuum glass tubes 2 coinciding with elongated axes of these two-surface vacuum glass tubes 2. The vortex tube! is mounted in the insulated hood 4, in which space the system of the two-faced vacuum glass tubes 2 is also detachably connected to the first open side. The other side of the two-faced vacuum glass tubes 2 is hermetically sealed. To one side of the vortex tube 1, the input 5 is connected to pressurized water, the source of which is a pump. This water is passed through the vortex tube 1 and the rod nozzles 3 in the two-surface vacuum glass tubes 2, where it comes to its heating. The heated water is then led out into the space formed by insulated hood 4 and led through the outlet 6 from this hood 4 to the exchanger or boiler and further turned on in the desired circle of the warm water of the heating system or directly to the hot water consumer,

Example 5

The system for air heating according to FIG 4 is formed by the vortex tube I for air distribution, vertically oriented to which at an angle of 20 ° to the axis of the vortex tube X and in a plane at regular intervals, a number of rod nozzles 3 is firmly connected, the form inclined system of rod nozzles 3 to distribute the air intended for heating. Each of the bar nozzles 3 is mounted in a double-surface vacuum glass tube 2 made of borosilicate glass, supplied with inner lining to increase the absorption of solar heat. The bar nozzles 3 are mounted in two-surface vacuum glass tubes 2 coinciding with oblong axes of this two-layered glass vacuum tube 2. The vortex tube 1 is mounted in the space formed by the insulated hood 4, where also with its first open side, the system formed by two-surface vacuum glass tubes 2 is detachably connected. The other side of the two-surface vacuum glass tubes 2 is hermetically sealed. To one side of the vortex tube i, the input 5 of the compressed air is connected, the source of which is a fan. As a source, for example, a compressor can be used. This air is through the vortex tube l and 7

• * * »I ······································································································································································································································································· comes. The heated air is then led out into the space formed by insulated hood 4 and through the entrance 6 from this hood 4 to the collection point for further processing of this heated air or directly into the heated space.

Example 6

The plant for heating water according to FIG 4 is formed by the vortex tube l for water distribution, vertically oriented, to which at an angle of 20 ° to the axis of the vortex tube \ and in a plane at regular intervals, a series of rod nozzles 3 is firmly connected, the form obliquely mounted system of rod nozzles 3 for distributing the water intended for heating. Each of the bar nozzles 3 is mounted in a double-surface vacuum glass tube 2 made of borosilicate glass, supplied with inner lining to increase the absorption of solar heat. The rod nozzles 3 are mounted in two-surface vacuum glass tubes 2 coinciding with elongated axes of these two-surface vacuum glass tubes 2. The vortex tube 1 is mounted in the space formed by the insulated hood 4, where also with its first open side, the system formed by two-surface vacuum glass tubes 2 is detachably connected. The other side of the two-surface vacuum glass tubes 2 is hermetically sealed. To one side of the vortex tube i the input 5 of the pressurized water is connected, the source of which is a pump. This water is passed through the vortex tube 1 and through rod nozzles 3 in the two-surface vacuum glass tubes 2, where it comes to its heating. The heated water is then led out into the space formed by insulated hood 4 and supplied through the outlet 6 from this hood 4 to the exchanger or boiler and it was turned on in the desired circle of hot water of the heating system or directly to the hot water consumer.

The examples of implementation given are only for illustration, it is possible to use both combinations of the cited examples of the application, as well as those of other modulations. The advantage of the possibility of using the system according to this utility model is the possibility of switching into the circuit with a heat pump and thus the possibility of a further increase in efficiency of the system and the cost reduction on heating of the object or on the Warmwasserliferung,

The plant for air or water heating according to this technical solution is useful both in households, as well as in industrial plants and especially in the transitional seasons, when the usual heating means are not used.

The system can be used in combination with photovoltaic elements to drive the compressed air or water source even without secure power supply of e.g. in bungalows, in campings, in huts, in research expeditions in inaccessible terrain, etc. to be used. 8th

Claims (7)

CZ 21199 Ul PROTECTION CLAIMS 1. The air or water heating system, formed by a vortex tube (1), the system of bar nozzles (3), the system of two-faced vacuum glass tubes (2), the insulated hood (4) and compressed air or pressurized water source, characterized in that the vortex tube (1), stored in the space formed by the insulated hood (4), perpendicular and / or obliquely with respect to its elongate axis at least one row of rod nozzles (3), in a plane and in connected at regular intervals, wherein the vortex tube (1) is arranged horizontally or vertically, and the rod nozzles (3) are mounted in accordance with the elongated axes of the two-surface vacuum glass tubes (2) in these two-surface vacuum glass tubes (2), wherein the two-surface vacuum glass tubes (2 ) with an open side in the through the insulated hood (4) of the vortex tube (1) by means of formed in the sheath of the insulated hood (4) removably openings are switched. 2. The plant for air or water heating according to claim 1, characterized-characterizing that to one side of the vortex tube (1) of the input (5) of compressed air or pressurized water is connected, and on the other side of the vortex tube (1) its insulated hood (4) the output (6) is connected to the discharge of heated air or heated water. 3. The plant for air or water heating according to claim 2, characterizing in that the source of compressed air is a fan and / or compressor, and that the discharge of the heated air discharged directly into the room for dehydration, or to a further system for Processing of this heated air is connected. 4. The plant for air or water heating according to claim 2, characterizing in that the source of pressurized water is a pump, and that the discharge of the heated water to the exchanger or boiler out, and is further turned on in the desired circle of hot water of the heating system , 5. The plant for air or water heating according to claim 3, .dadurch characterizing that the discharge of the heated air is turned on in the circuit with the heat pump. 6. The plant for air or water heating according to claim 4, characterizing that the discharge of the heated water is turned on in the circle of hot water. 7. The plant for air or water heating according to claims 1 and 2, characterized in that the vortex tubes (1) and rod nozzles (3) are made of a thermally conductive material. 2 drawings