IT202000016147A1 - REFRIGERANT DISTRIBUTION DEVICE FOR A HEAT PUMP AND CORRESPONDING HEAT PUMP - Google Patents

Description

DESCRIPTION

of the patent for industrial invention entitled:

?REFRIGERANT DISTRIBUTION DEVICE FOR A HEAT PUMP AND CORRESPONDING HEAT PUMP?

The present invention ? relating to a refrigerant distribution device for a heat pump and a corresponding heat pump.

In particular, the present invention finds advantageous, but not exclusive application in an air-water heat pump, to which the following description will make explicit reference without losing in generality?.

As ? known, an air-water heat pump comprises a circuit in which a refrigerant fluid circulates on which a refrigeration cycle is performed. The circuit includes, in the following order defined by the direction of circulation of the refrigerant fluid, at least one evaporator, which ? equipped with a respective finned heat exchanger and ? able to absorb heat from the air through the evaporation of the refrigerant, a compressor to compress the refrigerant, a condenser, which ? equipped with a heat exchanger to transfer heat from the refrigerant fluid to a second fluid, in this case water, and at least one expansion valve, which ? connected to the inlet of a respective evaporator to reduce the pressure of the refrigerant before it enters the evaporator. The coolant? in the liquid phase at the inlet of the expansion valve, while ? composed of two phases, liquid and gaseous, at the outlet of the expansion valve.

When the air-water heat pump includes more? evaporators, the latter are connected to operate in parallel and typically the air-water heat pump includes as many expansion valves as there are evaporators. The inlets of the expansion valves are connected to the duct that comes from the condenser by one or more? T-connectors. In this way, the refrigerant is distributed to the expansion valves when ? in the liquid phase and therefore there is the substantial certainty that the flow of the refrigerant fluid is divided into substantially equal parts and therefore is fed in quantity? equal to the evaporators, thus ensuring? correct operation of the air-to-water heat pump.

However, an air-to-water heat pump having a plurality of of expansion valves ? more complex to install and to calibrate compared to one having only one expansion valve.

The best solution? immediate to overcome these disadvantages would be to adopt a single expansion valve and to connect its output to the various evaporators through one or more? T-connectors. With this configuration, the refrigerant fluid is fed to the evaporators when ? in the two liquid and gaseous phases and therefore there is no c?? the certainty that the flow of refrigerant fluid is divided into quantities? equal between the evaporators. In other words, ? very probable that some evaporators are supplied with a greater percentage of liquid phase of the refrigerant fluid and others with a greater percentage of gaseous phase, and what? ? unwanted why? causes unbalanced operation of the air-to-water heat pump.

Purpose of the present invention? to produce an air-water heat pump, which is free from the drawbacks described above and, at the same time, is easy and cheap to produce.

In accordance with the present invention, a device for distributing a refrigerant fluid is provided for a heat pump and a heat pump as defined in the attached claims.

This invention will come now described with reference to the attached drawings, which illustrate a non-limiting embodiment thereof, in which:

- figure 1 illustrates a diagram of an air-water heat pump comprising the device for distributing a refrigerant fluid of the present invention;

figure 2 illustrates the device for distributing a refrigerant fluid of the heat pump of figure 1 in a simplified manner and according to a sectional view along a longitudinal plane of symmetry;

figure 3 illustrates the device for distributing a refrigerant fluid of the heat pump of figure 1 in a simplified manner and according to a sectional view along a transversal plane, indicated in figure 2;

- figure 4 illustrates the dispensing device during use according to the sectional view of figure 2.

In figure 1, with 1 ? generally indicated, as a whole, a heat pump, in particular an air-water heat pump, which comprises a circuit 2 in which a refrigerant circulates, according to a circulation direction 3, on which a refrigeration cycle is performed .

The circuit 2 comprises, in the following order defined by the direction of circulation 3, a plurality of 4 evaporators, which are connected to operate in parallel and each of which ? equipped with a respective finned heat exchanger 5 and ? adapted to absorb heat from the air through the evaporation of the refrigerant fluid, a compressor 6 for compressing the refrigerant fluid, a condenser 7, which ? provided with a heat exchanger (not shown) for transferring heat from the refrigerant fluid to a second fluid, in this case water, which circulates in another circuit 8, and a single expansion valve 9, which ? connected upstream, respectively to the circulation direction 3, of the evaporators 4.

Does heat pump 1 include at least one or more? 10 fans, each of which ? placed in front of one or more? finned heat exchangers 5 to force the passage of air through the fins of the finned heat exchangers 5. In the example illustrated by figure 1, the heat pump 1 comprises four evaporators 4 and two fans 10, each of which ? arranged in front of the finned exchangers 5 of a pair of evaporators 4.

The circuit 2 comprises a distribution device for the refrigerant fluid, indicated by 11 in figure 1, connected between the outlet 9a of the expansion valve 9 and the inlets 4a of the evaporators 4. In particular, the distribution device 11 comprises a body tubular 12 having a longitudinal axis 12a and having an axial inlet 13, i.e. coaxial to the longitudinal axis 12a, connected to the outlet 9a of the expansion valve 9, and a plurality of transversal outlets 14, and in particular four outlets 14, each of which ? connected to the input 4a of a respective evaporator 4. The distribution device 11 ? suitable for dividing the flow of the refrigerant supplied by the expansion valve 9 into a plurality? of flows of equal size, in the example four flows, and to feed them to the respective evaporators 4.

With reference to figure 2, which illustrates the distribution device 11 in a simplified manner and according to a sectional view along a vertical and longitudinal plane of symmetry, i.e. a plane on which the longitudinal axis 12a lies, the tubular body 12 ? arranged with its longitudinal axis 12a in a horizontal position.

The distribution device 11 comprises, in addition to the tubular body 12, a plurality of ducts 15, which extend transversely and at least partially in the tubular body 12 in such a way that their respective ends outlets 16 for the outlet of the refrigerant fluid protrude above the tubular body 2 and their respective ends of inlet 17 for the inlet of the refrigerant fluid are arranged near? of a lower wall portion 18 of the tubular body 12, and a septum 19, which is arranged inside the tubular body 2 between the axial inlet 3 and the ducts 15.

The septum 19 divides the internal volume of the tubular body 12 substantially into a first volume 20, which communicates directly with the axial inlet 13, and a second volume 21, in which the ducts 15 are housed. The septum 19? dimensioned in such a way as to leave at least one lower opening 22 and at least one upper opening 23, i.e. an opening 22 above the partition 19 and an opening 23 below the partition 19, which connect volume 20 with volume 21.

The number of ducts 15 ? equal to the number of evaporators 4. The extremities? 16 of the ducts 15 are provided with respective connectors for connection, each, with the inputs 4a of a respective evaporator 4, these connectors defining the outputs of the distribution device 11 and therefore are indicated with the same number 14 also in figure 2 .

Each of the ducts 15 has its own section 24 inside the tubular body 12 which has a plurality of of 25 holes distributed longitudinally. The holes 25 pass through to put the volume 21 of the tubular body 12 in communication with the inside of the duct 15.

The ducts 15 have the same diameter and the same length. The holes 25 of each conduit 15 are equal to each other. There? ease? to the construction of the duct 15 as ? only one drill bit required. The holes 25 of a duct 15 are identical in number and size to the holes 25 of any other duct 15. In summary, the ducts 15 are identical to each other.

Advantageously, the holes 25 of each duct 15 are distributed regularly, i.e. at a constant distance between adjacent holes, along the relative section 24.

Advantageously, the section 24 with the holes 25 of each conduit 15 is substantially centered on the longitudinal axis 12a of the tubular body 12.

Advantageously, the ducts 15 are parallel to each other, as shown in figure 2. Advantageously, the axis 15a of the ducts 15 is? transversal to the longitudinal axis 12a. Preferably, the axis 15a of the ducts 15 is perpendicular to the longitudinal axis 12a, therefore the extremities? outlets 16 of the ducts 15 and protrude radially from the tubular body 12 and the outlets 14 are radially oriented.

Preferably, the tubular body 12 has a cylindrical shape with a substantially circular or elliptical cross-section and therefore this cross-section has at least one axis of transverse symmetry. In the case of a circular section, the transverse symmetry axis coincides with the diameter of the circular section. Preferably, the section 24 with the holes 25 of each duct 15 extends substantially through the entire volume 21 along an axis of transversal symmetry of the tubular body 12.

Advantageously, the extremities? of inlet 17 have respective openings 17a having the same section for the inlet of the refrigerant fluid. Each opening 17a ? defined by a cut of its extremity? inlet 17, oblique with respect to the axis 15a. In particular, the section of the opening 17a defined by the oblique cut ? inclined at 45? with respect to the axis 15a of the relative duct 15.

Advantageously, the opening 17a defined by the oblique cut ? facing so as to have septum 19 behind.

The extremities? of inlet 17 are fixed to the lower wall portion 18, for example by welding. The extremities? inlet 17 cut obliquely and fixed to the portion of the lower wall 18 allow the entry of the refrigerant fluid and at the same time allow to increase the rigidity? of the distribution device 11.

Advantageously, the septum 19 ? transversal to the longitudinal axis 12a, and in particular perpendicular to the longitudinal axis 12a. In the example illustrated by figure 2, the septum 19 ? made up of a flat element.

Figure 3 illustrates the distribution device 11 according to a sectional view along a plane transverse to the longitudinal axis 12a, this transversal plane being disposed between the two ducts 15 pi? close to the septum 19 and indicated by AA in figure 2. With reference to figure 3, the tubular body 12 has a circular section and therefore the aforesaid transversal symmetry axis of the tubular body 12 coincides with the diameter of the circular section. The openings 22 and 23 are defined between two respective arcs of circumference 22a and 23a of the circular section and the two chords 22b and 23b subtended by the two arcs of circumference 22a and 23a, the chords 22b and 23b being parallel to each other, and the septum 19 ? an element limited at the bottom and top between the two strings 22b and 23b.

With reference to figure 4, in use, a flow of refrigerant fluid, indicated with 26, enters the tubular body 12 from the axial inlet 13 and impacts against the partition 19.

The stream 26 ? coming from the expansion valve 9 and then ? normally two-phase, i.e. it includes the liquid phase and the gaseous phase of the refrigerant fluid. In other words, the stream 26 comprises a refrigerant in the liquid phase in which a large quantity of of gas phase bubbles, indicated with 27.

The impact of the flow 26 against the septum 19 favors the separation between the liquid phase and the gaseous phase of the refrigerant fluid, since after the impact the liquid phase descends by gravity and, through the lower opening 22, passes into a lower portion 28 of the volume 21, and the gaseous phase rises and, through the upper opening 23, passes into an upper portion 29 of the volume 21.

The extremities? inlet pipes 17 are therefore arranged in the lower portion 28 of the volume 21 in such a way as to receive, by aspirating it, the liquid phase of the refrigerant fluid, thanks to the head generated by the compressor 6 in the circuit 2.

The liquid phase of the refrigerant fluid therefore rises in the ducts 15 creating a suction effect through the holes 25. In the example illustrated by figures 2-4, the section 24 with the holes 25 of each duct 15 is substantially centered on the longitudinal axis 12a of the tubular body 12 and therefore some holes 25 are arranged in the lower portion 28 of the volume 21 and the other holes 25 are arranged in the upper portion 29 of the volume 21. Therefore, the suction effect in the ducts 15 causes the aspiration of the liquid phase of the refrigerant fluid through those holes 25 which are found in the lower portion 28 and the aspiration of the gaseous phase of the refrigerant fluid through those holes 25 which are found in the upper portion 29.

The diameter of the ducts 15? chosen in such a way that the speed? rise of the liquid phase of the refrigerant fluid inside the ducts is sufficient to create the aforesaid suction effect through the holes 25.

For example, the ducts 15 have an internal diameter of between 5 and 15 mm, in particular between 6 and 12 mm.

The diameter of the holes 25 ? sized according to the desired gaseous phase flow rate of the refrigerant fluid drawn through the holes 25. For example, the holes 25 have a diameter of between 1.5 and 7.5 mm, in particular between 2 and 6 mm.

The number of holes 25 is chosen to obtain, under the nominal operating conditions of the circuit 2, that the level of the liquid phase of the refrigerant fluid in the volume 21 is approximately half of the internal height of the tubular body 12, ie the longitudinal axis 12a lies on a plane which substantially defines the level reached in use by the liquid phase. So volume 21? substantially equally divided into the lower portion 28 and the upper portion 29.

The tubular body 12 ? sized in such a way as to allow the housing of a desired number of ducts 15 having a length such as to produce the aforesaid suction effect. The cross section of the tubular body 12, and in particular the diameter, is sized according to the refrigerant flow rate of circuit 2 in order to reduce the speed? of the fluid inside the tubular body 12 to a value such as to avoid turbulence phenomena which would keep the liquid and gaseous phases of the refrigerant mixed.

Furthermore, the cross section of the tubular body 12 is sized to allow the insertion of ducts 15, each of which has holes 25 in such a number and diameter as to guarantee the aforesaid suction effect along the ducts 15.

For example, the tubular body 12 has a circular section having a diameter between 60 and 170 mm, in particular between 80 and 150 mm.

The size of the septum 19 ? function of the cross section of the tubular body 12. The lower opening 22 ? sized to such an extent as to allow the passage of the liquid phase of the refrigerant fluid without excessive increases in the flow 26 before impact with the septum 19. The upper opening 23 is? sized to such an extent as to allow the passage of the gaseous phase of the refrigerant fluid at a speed? low enough to avoid the transport of liquid droplets in the gas stream. In particular, the section of each of the openings 22 and 23 ? substantially equal to the section of the axial entrance 13.

Thanks to the fact that the ducts 15 are identical to each other, each of them sucks and conveys substantially the same quantity at the outlet 14 of refrigerant fluid, i.e. the outlets 14 of the distribution device 11 feed the respective flows to the evaporators 4 with the refrigerant fluid, indicated by 30 in Figure 4, having substantially the same ratio between the quantity? of liquid phase and quantity? of gaseous phase.

Bench? the invention described above makes particular reference to a very precise example of embodiment, it is not? to be considered limited to this example of embodiment, all those variants, modifications or simplifications covered by the attached claims falling within its scope, such as for example:

- the openings 22 and 23 are formed in the element which defines the partition 19;

- each duct 15 ? without the opening 17a defined by the oblique cut of the extremity? 17 and the liquid phase of the refrigerant enters the duct 15 from the holes 25 present in the lower portion 28 of the volume 21;

- the section 24 with the holes 25 of each duct 15 ? all contained in the upper portion of the volume 21 in such a way that only the gaseous phase of the refrigerant fluid enters through the holes 25; And

- each conduit 15 has a single hole 25 arranged in the upper portion 29 of the volume 21 in such a way that the liquid phase of the refrigerant fluid enters the conduit 15 only from the opening 17a at the end? inlet 17 and the gaseous phase enters the duct 15 only from the single hole 25.

The advantage of the distribution device 11 described above? to allow an equal division of the quantity? of the refrigerant fluid fed to a plurality? of evaporators 4 of a heat pump 1 while using only one expansion valve 9, regardless of the number of evaporators 4 present in the heat pump 1.

Also, the distribution device 11 ? extremely simple to make and pu? be used for any type of heat pump and not just for an air to water heat pump.

Claims (11)

1. Distribution device for a refrigerant fluid for a heat pump (1) comprising a circuit (2), in which the refrigerant fluid circulates and which comprises at least two evaporators (4) connected in parallel and a single expansion valve ( 9); the device (11) comprising: a tubular body (12), which ? positionable with its own horizontal longitudinal axis (12a) and comprises an axial inlet (13) for the inlet of the refrigerant fluid, which can be connected to an outlet (9a) of the expansion valve (9); a septum (19), which ? arranged in the tubular body (12) to divide its internal volume into a first volume (20) communicating directly with said axial inlet (13) and a second volume (21); at least one lower opening (22) and one upper opening (23) arranged below and, respectively, above the septum (19) to put the first volume (20) in communication with the second volume (21), in such a way that, in use , the refrigerant entering from the axial inlet (23) and impacting against the septum (19) separates into a liquid phase, which descends and, through the lower opening (22), passes into a lower portion (28) of the second volume (21), and a gaseous phase, which rises and, through the upper opening (23), passes into an upper portion (29) of the second volume (21); and at least two ducts (15), which are identical to each other and extend transversely in the tubular body (12) to be housed at least partially in the second volume (21), so that the first ends? (16) of the ducts (15) for the outlet of the refrigerant fluid protrude above the tubular body (12) and can be connected to respective inlets (4a) of the evaporators (4) and second ends? (17) of the ducts (15) are arranged in said lower portion (28) of the second volume (21) and have respective openings (17a) for the inlet of the liquid phase of the refrigerant fluid; each of the ducts (15) having at least one hole (25) arranged in said upper portion (29) of the second volume (21) for the inlet of the gaseous phase of the refrigerant fluid. 2. Device according to claim 1, wherein said at least one hole (25) comprises a plurality of of holes (25) distributed longitudinally along a section (24) of the relative duct (15). 3. Device according to claim 2, wherein said section (24) of the duct (15) extends up to inside said lower portion (28) of the second volume (21) in such a way that some of the holes of said plurality? of holes (25) receive said liquid phase of the refrigerant fluid. 4. Device according to claim 2, wherein said section (24) of the conduit (15) conduits (15) ? substantially centered on said longitudinal axis (12a) and preferably extends substantially throughout said second volume (21) along an axis of transverse symmetry of said tubular body (12); preferably said tubular body (12) ? a circular cylindrical body and said axis of transverse symmetry ? the diameter of the circular cylindrical body. 5. Device according to any one of claims from 2 to 4, wherein the holes of the plurality? of holes (25) are regularly distributed along said section (24) of the relative duct (15). 6. Device according to any one of claims from 1 to 5, wherein said at least two ducts (15) are parallel to each other, preferably having respective axes (15a) perpendicular to said longitudinal axis (12a). 7. Device according to any one of claims from 1 to 6, wherein each of said openings (17a) of said second ends? (17) of said ducts (15) ? defined by a cut of its second end? (17), the cut being oblique with respect to an axis (15a) of the relative duct (15), and the second ends? (17) are fixed to a lower wall portion (18) of the tubular body (12). 8. Device according to claim 7, wherein the opening (17a) of each of said second ends? (17) defined by said oblique cut ? facing so as to have said septum (19) behind. 9. Device according to any one of claims from 1 to 8, wherein said septum (19) ? transversal to said longitudinal axis (12a), in particular perpendicular to said longitudinal axis (12a). 10. Device according to any one of claims from 1 to 9, wherein said tubular body (12) ? a circular cylindrical body. 11. Heat pump comprising a circuit (2), in which a refrigerant fluid circulates and which comprises at least two evaporators (4) connected in parallel and having respective inlets (4a) for the refrigerant fluid, and a single expansion valve ( 9) having an outlet (9a) for the refrigerant fluid; the heat pump (1) being characterized in that the circuit (2) comprises a refrigerant fluid distribution device according to any one of claims 1 to 10, wherein said axial inlet (13) ? connected to the outlet (9a) of the expansion valve (9) and each of said first ends? (16) ? connected to the inlet (4a) of a respective evaporator (4).