Patent Application
20240183542
The object of the present invention is a storage water heater or the like, preferably used for the production of domestic hot water.
More in detail, the present invention refers to a storage water heater provided with at least a main heater and at least a additional/auxiliary heater.
Even more in detail, the present invention refers to a storage water heater heated by at least a main heater and provided with at least a first and/or second additional/auxiliary heater.
A further object of the present invention is a management method of a storage water heater and of the heating elements thereof.
Storage water heaters are currently known provided with a main and additional heater arranged within the storage tank of the water to be heated.
Generally, said additional heater comprises one or more electric resistances which, by conduction, heat the water wherein they are immersed.
Such type of water heater presents different drawbacks.
The main one is linked to the fact that the contact with water causes the electrical resistance to have a gradual deterioration and loss of efficiency due to the formation of limescale or the like.
During the use, therefore, the electrical resistance requires maintenance or a replacement thereof, increasing the management costs of the same water heater.
Another problem of the current water heaters, concerns the overall dimensions and size thereof strictly related to the shape and capacity (volume) of the tank, but also to the overall dimensions of the heating elements provided for by the same water heater.
Currently, water heaters that are compact and with small overall dimensions are preferred and such preference is not always met by the water heaters offered on the market.
This is due to the type of heating elements installed by the water heater.
For example, the heat pumps, which are more and more applied in the sector of the storage water heaters, have significant overall dimensions due to the presence of heat exchangers (evaporator/condenser) which require certain heat exchange surfaces and the presence of essential components, such as for example compressors or others, in order to carry out their function.
The water heaters currently available, therefore, do not fully meet the needs of the market which requires small overall dimensions and low management/maintenance costs.
The aim of the present invention is to obviate such kind of drawbacks by providing a storage water heater or the like, preferably for the production of domestic hot water, able to keep low the overall dimensions.
A further object of the present invention, at least for one or more executive variants, is to provide a storage water heater or the like provided with at least a main heater and at least a additional/auxiliary heater.
A further object of the present invention, at least for one or more executive variants, is to provide a management method of a storage water heater and of the heating elements thereof.
These and other objects, which shall appear clear hereinafter, are achieved with a storage water heater or the like and relative management method, according to claim 1.
Other objects may also be achieved by means of the additional features of the dependent claims.
Further features of the present invention shall be better highlighted by the following description of a preferred embodiment, according with the patent claims and illustrated, purely by way of a non-limiting example, in the accompanying drawing tables, in which:
The features of a storage water heater or the like according to the present invention and of the relative management method are now described using the references contained in the figures.
The parameters and functions/conditions and the respective references used hereinafter in the description are listed below:
It should be noted that the arrows shown in the accompanying figures essentially indicate the path of the water entering and exiting the water heater according to the present invention.
The term storage water heater is herein to be understood as any device capable of heating water in a storage tank, in particular domestic hot water for hygienic uses, until reaching a certain temperature herein defined as the set-point temperature T.set.
As clearly shown in the accompanying figures, 1 indicates, as a whole, the storage water heater 1 according to the present invention, hereinafter referred to as only water heater 1, for clarity of description.
Generally, said water heater 1 may comprise at least a heating device, at least a storage tank 10 wherein water is stored and heated, at least a control and management unit capable of controlling said at least a heating device, at least a inlet duct 11 through which water may be introduced into the tank 10, at least an outlet duct 12 through which water may be sent/withdrawn from the tank 10, said inlet ducts 11 and 12 being in fluid communication with said tank 10.
The heating device may be of the electric type, i.e. comprising at least a electric device such as for example electric resistances or the like, or of the heat pump type, a variant illustrated by way of a non-limiting example in the accompanying figures, solar energy, gas, geothermal or the like or possible combinations thereof.
Generally, in a storage water heater the water inside the storage tank has a stratification according to the temperature, said stratification being due to the heating process caused by the heating elements and by the density of the water.
In fact, the hottest water tends to migrate and settle in the top part of the tank, while the colder water tends to settle in the lower part of the same tank.
According to a preferred variant, the outlet section 110 of the inlet duct 11 is preferably positioned in the proximity of the lower zone of the said tank 10, while the inlet section 120 of the outlet duct 12 is preferably positioned in the proximity of the median or, even more preferably, top zone of the said tank 10.
During the operation of the water heater 1, such arrangement determines a water make-up, generally from the water network, in the lower area of the tank 10 and a withdrawal of hot water in the upper zone thereof, thus keeping the stratification of the water based on the temperature thereof and essentially guaranteeing the withdrawal and supply of hot water.
According to a preferred variant, said water heater 1 comprises at least two heating devices, of which preferably at least a main and at least a auxiliary.
In general, “main” heating device refers to as a device which is designed to heat water in normal/standard conditions, while “auxiliary” is to be understood as a device designed to heat water in particular conditions, for example when it is preferable to have a heat source in addition to the main one.
Of said at least two heating devices may be identified:
Preferably, according with a possible executive variant, shown by way of a non-limiting example in the accompanying figures:
Preferably, according to possible executive variants, said second device 4 may be installed along the inlet duct 11, so as to act as a pre-heater, i.e., be able to heat the make-up water entering the tank 10, hereinafter referred to as pre-heater 4.
According to a possible embodiment variant, provided by way of a non-limiting example, said water heater 1 may further comprise at least a third heating device 5, herein identified as “auxiliary”, which may comprise heaters, preferably of the instantaneous type, comprising, for example, electric heaters, electric resistances or the like.
Said third auxiliary device 5 is preferably installed along the outlet duct 12 so as to be able to act as a post-heater, i.e. be able to heat the water supplied exiting the tank 10, hereinafter referred to as post-heater 5, and may be arranged externally to said storage tank 10.
In such case, therefore, said water heater 1 simultaneously comprises at least a pre-heater 4 and at least a post-heater 5.
Generally, it is possible to use an auxiliary device, both when it acts as a pre-heater 4 and when it acts as a post-heater 5, which may be equipped with power regulating means which allow the energy supply, provided by the auxiliary device to be managed in relation to the comparison between the energy contents: of the storage water and of the recirculation water and/or of the storage water and of the make-up and/or of the storage water and of the water supplied by the water heater 1.
According to a preferred variant, said second device 4 is installed upstream of the outlet section 110 of the inlet duct 11, while said third device 5 is installed downstream of the inlet section 120 of the outlet duct 12.
The arrangement of said second 4 and third 5 heating device, which, as said, are preferably external to the tank 10, allows for a convenient inspection and a possible easy replacement thereof.
For clarity of description, the inlet and outlet sections of the pre-heater 4 and of the post-heater 5, as well as the inlet 11 and outlet 12 ducts whereon they may be installed, are defined in relation to the normal operation of water heater 1, i.e. to the making up cold water and supplying hot water during a withdrawal in progress.
The water heater 1 may further comprise:
Preferably, said sensors are suitably connected and communicating with said control unit.
In general, said flow sensor 60 may be installed along the inlet duct 11.
Nothing prevents said flow sensor 60 from being installed along the outlet duct 12, as the general purpose of the flow sensor 60 is to detect whether or not a water withdrawal/make up from/into the tank 10 is in progress.
In general, it is possible to evaluate and classify the withdrawal in progress as small or large by comparing the value of the flow F detected by the flow sensor 60 with the reference value FL.
The water heater 1 is characterised in that it comprises at least a by-pass duct 13, hereinafter referred to as only by-pass 13 for descriptive convenience, capable of deviating, entirely or partially, the water flow entering the tank 10 so as to guide and convey it in a zone of the tank 10 placed at a height higher than the outlet section 110 of the inlet duct 11 and at a height lower than the inlet section 120 of the outlet duct 12.
Preferably, therefore, said by-pass 13 guides and conveys the water entering the tank 10 in a zone of the said tank 10 comprised between the outlet section 110 of the inlet duct 11 and the inlet section 120 of the outlet duct 12.
Said by-pass 13 substantially extends between the inlet duct 11, to which it is connected, and the zone of the tank 10 wherein it discharges/introduces the make-up water, said by-pass 13 being suitably shaped so as to comprise:
Preferably, the position of said outlet 131 inside the tank 10 may be varied as necessary so that said outlet 131 may be located in the upper or middle or lower zone of the said tank 10, substantially regulating, for example, the longitudinal extension of the said by-pass 13.
Such possible adjustment of the position of the outlet 131 of the by-pass 13 allows the distance “h” to be adjusted and defined, while maintaining fixed the position of the inlet section 120 of the outlet duct 12 (see
In essence, by increasing/reducing the longitudinal extension of the said by-pass 13, the distance h is reduced/increased and consequently the volume “y”.
The choice of the value of the distance h, which may be made in the design or construction step, allows the entity of the volume “v” and therefore the quantity of water of the storage heated through the introduction of hot water heated by the pre-heater 4 to be determined/modified, according to the methods described shortly, and introduced via the by-pass 13.
As described below, by reducing the volume v, the make-up water, heated by the pre-heater 4, mixes, by heating it with a smaller quantity of water of the storage, making the water heater 1 more ready to satisfy the user.
According to different executive embodiments, the by-pass 13 provides for at least a portion 134, herein referred to as outlet portion 134, which develops and is housed inside the tank 10 and whereon said at least a outlet 131 is obtained/placed.
Preferably, said outlet portion 134 is arranged substantially vertically inside the tank 10 and extends from a zone in the proximity of the bottom of the same tank 10, preferably engaging from the same bottom, to a median or upper zone of the tank 10 based on the longitudinal development thereof correlated to the established/chosen distance h.
According to a possible variant, the by-pass 13 may be shaped substantially as an “L” or the like so as to be able to provide for:
According to different executive embodiments of the present invention, all falling within the same inventive concept, it is possible to identify at least two different installations of the pre-heater 4 identified and illustrated herein, by way of a non-limiting example, as Case A and Case B.
According to such variant, said pre-heater 4 is preferably positioned and installed along the inlet duct 11 (see for example the variants of
Preferably, the inlet 130 of the said by-pass 13 is placed along the inlet duct 11 downstream of the pre-heater 4, i.e. between the outlet 41 of the pre-heater 4 and the outlet section 110 of the inlet duct 11, preferably externally with respect to the tank 10.
According to such variant, said pre-heater 4 is preferably positioned and installed along the by-pass duct 13 (see for example the variant of
Preferably, the inlet 130 of the said by-pass 13 is placed along the inlet duct 11 upstream of the inlet 40 of the pre-heater 4.
Preferably said water heater 1 is further provided with at least a diverter means 8, hereinafter referred to as diverter valve 8, preferably of the electrically or mechanically controllable type, such as for example solenoid valves, motorised valves or the like, adapted to connect said by-pass duct 13, preferably the inlet 130 thereof, to said inlet duct 11.
Said diverter valve 8, based on the type thereof, is capable of deviating the water entering the tank 10 either towards the by-pass 13 or towards the outlet section 110 or of possibly dividing it between both according to proportions set by the manufacturer and/or installer and/or user.
For example, said diverter valve 8 may be of the type:
According to a preferred variant, a controllable diverter valve 8 is placed along the inlet duct 11 in the section in which the by-pass 13 engages said inlet duct 11, said diverter valve 8 therefore acting as a union and connecting element among the parts and being also able to be installed externally to the tank 10.
In essence, along the inlet duct 11 there is a diverter valve 8 capable of deviating, entirely or partially, the flow of make-up water entering the tank 10 so that it may be:
In general, the make-up water, in the entirety or a portion thereof, may be advantageously heated or pre-heated through the pre-heater 4 according to methods described shortly.
In particular, with reference to the variant of the Case A, it should be noted that the entire make-up water is heated, regardless of whether it is introduced into the tank 10 via the inlet duct 11 only (mode i) or the by-pass 13 only (mode ii) or via both (mode iii), while in the variant of the case B only the make-up water which is diverted and passed through the by-pass 13 is heated.
Some considerations regarding the heating and the introduction of the make-up water into the tank 10 are provided below.
In general, the water heater 1 is able to operate with the modes i), ii) and iii) reported above, regardless of whether the configuration thereof complies with the Case A or the Case B, said Cases A and B differing substantially only by the arrangement of the pre-heater 4.
Furthermore, the water heater 1 is able to operate in mode i) and/or ii) even if it is equipped with an adjustable type diverter valve 8, as it is sufficient to completely close the valve 8 to implement mode i) and open it completely to implement mode ii).
In such circumstance, the temperature Tc or Tset is reached more slowly, because the pre-heated water, introduced into the lower zone of the tank 10, tends to mix with all the water of the storage.
In such circumstance the achievement of the temperature Tc or Tset is quicker, at least for a portion v of the volume of the storage, since the pre-heated water, introduced at a distance h from the inlet section 120, tends to mix with the water of the volume v, said volume v being only a part/portion of the entire volume of the storage of the tank 10 (
Furthermore, the pre-heater 4 may heat the water substantially up to Tc, Tm or Tset or in general up to a temperature substantially similar to that of the water in the proximity of the zone of the storage into which it is introduced (ϑb), so as to preserve and meet the temperature stratification of the storage.
Such circumstance represents a hybrid/intermediate situation with respect to the methods i) and ii), the achievement of the temperature Tc or Tset being correlated to the adjustment degree of the diverter valve 8 and to the amount of make-up water which is introduced respectively via the by-pass 13 and the outlet section 110 (
Case B—Mode i), ii) and iii)
Generally, the configuration of the Case B, providing for heating only the make-up water which crosses the by-pass duct 13, allows the stratification of the tank 10, to be preserved more efficiently.
In fact, the make-up water introduced by means of the outlet section 110 of the inlet duct 11 is not heated and considering that it has a temperature substantially equal to the temperature of the water network, it does not substantially alter the stratification of the storage.
Such advantage is noticeable for the various water make-up methods of the Case B, because:
A possible management method of the water heater 1 shall now be described, by way of a non-limiting example, which may preferably be implemented via the control unit with which said water heater 1 is provided, said management method providing for different logics based on the fact that said water heater 1 comprises only the pre-heater 4 or both the pre-heater 4 and the post-heater 5 or is configured according to the Case A or the Case B or is equipped with an ON/OFF type or adjustable diverter valve.
Said control unit is therefore capable of controlling and commanding the different components of the water heater 1, such as for example the diverter valve 8, and/or both the main and auxiliary heating devices.
For better clarity of description, in
Furthermore, still with reference to
Said management method is aimed at controlling/coordinating different components of the water heater 1 such as, for example, at least the different heating devices of the water heater 1, both said at least a main device 2 and one or more of said auxiliary devices 4, 5 and/or at least the diverter valve 8, based on the functions to be implemented, whether standard/normal or additional.
The management method may consider different factors in order to implement such control/coordination, such as for example the presence/absence of a withdrawal, the number and/or type of said heating devices, and/or the set-point temperature Tset and/or the temperature Tc and/or the temperature of the storage water which may be possibly represented by one or more of the temperatures ϑu and/or ϑd and/or ϑb and or Tm and/or of the inlet 91 or outlet 90 water temperature.
Said management method is characterised in that it implements one or more supplementary heating functions, by one or more of said auxiliary devices 4, 5, of the water introduced and/or withdrawn from the storage, where the activation of at least one or more of said additional functions depending on at least:
In general, according to different possible executive variants, the non-activation or the deactivation of at least one or more of said additional functions may depend on at least the absence or end of a withdrawal.
Hereinafter, the term “no withdrawal”, without any limiting intent, is to be referred to as both the lack of a withdrawal and the end thereof, these conditions corresponding to measurements of the flow sensor 60 substantially equal to zero.
In general, said additional functions may comprise, for example, at least the BOOST function, the POST-HEATING function or the like.
Said management method of the water heater 1 may comprise at least the following phases.
The first phase P1, S1 of the method according to the present invention, provided by all the variants of said method illustrated herein, provides for verifying, via the flow sensor 60, whether or not a hot water withdrawal is in progress and based on such condition, two different possible operating/management logics may be implemented, one of which is dedicated to the case of a withdrawal and the other to the case of absence of a withdrawal.
With reference to
During a withdrawal (F≠0), said method provides for checking, through the phase P2, whether the BOOST function is selected or not.
If the BOOST function is selected, phase P21 is provided, by activating the pre-heater 4 (IST1=ON), while if the BOOST function is disabled the pre-heater 4 remains switched off (IST1=OFF), phase P20 and phase P4 is provided directly.
The BOOST function allows the make-up water to be heated, via at least said pre-heater 4, accelerating the heating of the storage and consequently reducing the time necessary to bring the storage substantially to Tset or to Tc.
With the BOOST function selected and the pre-heater 4 active, implementing the phase P22 with which there is checked whether the temperature ϑb is greater than the inlet one ϑ1 is provided.
If ϑb>ϑ1, the diverter valve 8 remains in “position 0” (M=0), maintaining the by-pass duct 13 closed and leaving the inlet duct 11 open, phase P24.
In such case, the make-up of pre-heated water takes place via the outlet section 110 of the inlet duct 11, in the lower part of the tank 10 which is then heated (
If there is no ϑb>ϑ1, the diverter valve 8 is switched to “position 1” (M=1) by opening, preferably totally, by-pass duct 13 and closing, preferably totally, inlet duct 11, phase P23.
In such case, the make-up of pre-heated water takes place via the outlet 131 of the by-pass 13, at a distance h from the inlet section 120 of the outlet duct 12 (
As anticipated, this allows the pre-heated water to be introduced into a zone in which the water of the storage, by virtue of the stratification phenomenon, has a higher temperature than the water of the storage in the proximity of the lower zone of the tank 10, speeding up the recovery of the storage at a temperature Tset or the attainment of the temperature Tc, in particular of the volume v.
Furthermore, in the event of a significant withdrawal (in terms of volume of water withdrawn) or of small but successive and close withdrawals, the make-up of the storage, via by-pass 13, of pre-heated water advantageously allows withdrawing hot or at least pre-heated water or in general with a temperature higher than the network temperature of the make-up water.
As partly anticipated, the pre-heated water may be brought, via the pre-heater 4, to a temperature substantially equal to Tc, Tm or Tset or in general up to a temperature substantially similar to that of the water in the proximity of the storage zone wherein it is introduced, i.e. substantially equal to ϑb.
The next phase P4 provides for monitoring the value of the temperature Tm by comparing it with Tset; the aim is not to allow the water of the storage to cool too much.
Following the comparison between Tm and Tset (phase P4):
Phase P40 is provided and implemented in the event that, as preferred, a hysteresis parameter X is subtracted from the temperature Tset in order to avoid frequent and subsequent re-ignitions of the main heating device 2.
Said phase P40 provides for comparing Tm with Tset-X and following said comparison:
The aim of the phase P43 is to check whether the main heating device 2 is switched on or not during the withdrawal.
In fact, the temperature at which the storage should be heated is Tset, and not Tset-X, therefore during a withdrawal:
In case of no withdrawals (F=0) or at the end of a withdrawal, said method provides for switching off or keeping the auxiliary heating device 4 switched off (IST1=OFF), phase P3.
In such conditions (F=0; IST1=OFF), the management method provides for implementing phase P4 so as to monitor the value of the temperature Tm and compare it with Tset; the aim is not to allow the storage water to cool too much due to possible heat losses or the like.
In absence of withdrawals, therefore, the auxiliary heating device is not active and the main heating device may possibly be activated following the comparison between Tm and Tset.
In such case, in fact, the average temperature Tm may vary mainly due to heat losses or the like which may lead to a progressive decrease in the temperature Tm.
In absence of withdrawals, therefore, the auxiliary heating devices are not active and the main heating device may possibly be activated following the comparison between Tm and Tset or between Tm and Tset-X according to the phases P40-P43 previously described.
In absence of a withdrawal, therefore, following the phase P43:
With reference to
During a withdrawal (F≠0) said method provides for checking whether the outlet water 90 meets the comfort temperature Tc; the aim is that of checking whether the water supplied meets the parameters set by the manufacturer and/or installer and/or user.
Such check is carried out with the phase S2, through which there is checked whether the outlet temperature ϑo of the water heater 1 is higher than or equal to the comfort temperature Tc (ϑo≥Tc), where:
Phase S21 provides for checking whether the BOOST function is selected or not.
In fact, the method, following the control of the output temperature ϑo, checks whether the BOOST function is set and selected or not.
If the BOOST function is selected, phase S23 is provided, by activating the pre-heater 4 (IST1=ON), while if the BOOST function is disabled the pre-heater 4 remains switched off (IST1=OFF), phase S22 and phase S4 is provided directly.
As already mentioned, the BOOST function allows the make-up water to be heated, via at least said pre-heater 4, accelerating the heating of the storage and consequently reducing the time necessary to bring the storage substantially to Tset or Tc.
With the BOOST function selected and the pre-heater 4 active, implementing the phase S24 with which there is checked whether the temperature ϑb is greater than the inlet one ϑ1 is provided.
If ϑb>ϑ1, the diverter valve 8 remains in “position 0” (M=0), maintaining the by-pass duct 13 closed and leaving the inlet duct 11 open, phase S26.
In such case, the make-up of pre-heated water takes place via the outlet section 110 of the inlet duct 11, in the lower part of the tank 10 which is then heated (
If there is no ϑb>ϑ1, the diverter valve 8 is switched to “position 1” (M=1) by opening, preferably totally, by-pass duct 13 and closing, preferably totally, inlet duct 11, phase S25.
In such case, the make-up of pre-heated water occurs via the outlet 131 of the by-pass 13, at a distance h from the inlet section 120 of the outlet duct 12.
As anticipated, this allows the pre-heated water to be introduced into a zone in which the water of the storage, by virtue of the stratification phenomenon, has a higher temperature than the water of the storage in the proximity of the lower zone of the tank 10, speeding up the recovery of the storage at a temperature Tset or the attainment of the temperature Tc, in particular of the volume v.
Furthermore, if the heat supplied by the pre-heater 4 and/or by the main heating device 2 is not sufficient to meet the requests of the user, supplying water at a temperature Tc, the post-heater 5 may intervene by providing the necessary heat.
The next phase S4 provides for monitoring the value of the temperature Tm by comparing it with Tset; the aim is not to allow the water of the storage to cool too much.
Following the comparison between Tm and Tset (phase S4):
Phase S40 is provided and implemented in the event that, as preferred, a hysteresis parameter X is subtracted from the temperature Tset in order to avoid frequent and subsequent re-ignitions of the main heating device 2.
Said phase S40 provides for comparing Tm with Tset-X and following said comparison:
The aim of the phase S43 is to check whether the main heating device 2 is switched on or not during the withdrawal.
In fact, the temperature at which the storage should be heated is Tset, and not Tset-X, therefore during a withdrawal:
In case of no withdrawals (F=0) or at the end of a withdrawal, said method provides for switching off or maintaining switched off the auxiliary heating devices (IST1=OFF; IST2=OFF), phase S3.
In such conditions (F=0; IST1=OFF; IST2=OFF), the management method provides for implementing the phase S4 so as to monitor the temperature value Tm and compare it with Tset; the aim is not to allow the storage water to cool too much due to possible heat losses or the like.
In absence of withdrawals, therefore, the auxiliary heating devices are not active and the main heating device may possibly be activated following the comparison between Tm and Tset, phase S4.
Following the comparison between Tm and Tset (phase S4):
Phase S40 is provided and implemented in the event that, as preferred, a hysteresis parameter X is subtracted from the temperature Tset, in order to avoid frequent and subsequent re-ignitions of the main heating device 2.
Said phase S40 provides for comparing Tm with Tset-X and following said comparison:
Phase S43 has the aim to check if the main heating device 2 is switched on or not.
In fact, the temperature to which the storage should be heated is Tset and not Tset-X, therefore in the absence of a withdrawal:
With reference to
The phases of the method provided for such variant are substantially the same as described with reference to the possible management method applied to a water heater which may be equipped with at least the BOOST function and provided with both the pre-heater 4 and the post-heater 5 and a diverter means 8 on/off (
As visible in
In fact, with the BOOST function selected and the pre-heater 4 active, implementing phase S24 is provided, with which there is checked whether the temperature ϑb is higher than the inlet one ϑ1.
If ϑb is not >ϑ1, phase S25′ provides for the diverter valve 8 to open, at least partially, said by-pass duct 13, i.e. that it is switched to a position comprised between 0<M≤1, i.e. the diverter valve 8 may take a position comprised between the position M>0 and the totally open position M=1, in other words the diverter valve 8 may not be totally closed in order to send water to the by-pass 13.
With reference to
The phases of the method provided for such variant are substantially the same as described with reference to the possible management method applied to a water heater which may be equipped with at least the BOOST function and provided with both the pre-heater 4, placed along the inlet duct 11, and the post-heater 5 and a diverter means 8 on/off (
As visible in
If the BOOST function is selected, phase S23′ is provided, by activating the pre-heater 4 (IST1=ON), and by fully opening the diverter valve 8 (M=1) while if the BOOST function is disabled the pre-heater 4 remains switched off (IST1=OFF), phase S22, and the following phase S4 is provided directly.
Subsequently, with the BOOST function selected and pre-heater 4 active, implementing phase S24 is provided, with which there is checked whether the temperature ϑb is higher than the inlet one ϑ1.
If ϑb is not >ϑ1, phase S25′ provides for the diverter valve 8 to open, at least partially, said by-pass duct (13), i.e. that it is switched to a position comprised between 0<M≤1, i.e. the diverter valve 8 may take a position comprised between the position M>0 and the totally open position M=1, in other words the diverter valve 8 may not be totally closed in order to send water to the by-pass 13.
If ϑb>ϑ1, the diverter valve 8 remains in “position 0” (M=0), closing or maintaining the by-pass duct 13 closed and leaving the inlet duct 11 open and pre-heater 4 is turned off or put in stand-by (IST1=OFF), phase S26′.
In such case the make-up water is not heated and is introduced at network temperature into the tank 10 via the outlet section 110 of the inlet duct 11.
In general, the water heater according to the present invention, thanks to the adoption of auxiliary heating devices, may install and use a smaller main heating device; that is further true in the case of the heat pumps.
In fact, heat pumps of lower power have smaller heat exchange surfaces (evaporator/condenser) and the overall size of the same heat pump will be reduced.
On the other hand, it is known that the electric heaters require, by their nature, reduced and compact overall dimensions and if they are used as auxiliary heating devices, the overall dimension of the water heater 1 is smaller than the overall dimension of a water heater of the same power which uses only one heat pump as a heating source.
Furthermore, the adoption of instantaneous heating devices allows the volume of the storage to be reduced, because such devices are able to effectively compensate for deep and frequent withdrawals by the user.
It should be noted that the adoption of smaller storages allows for the installation of smaller heat pumps, further contributing to reduce the overall dimensions of the water heater according to the present invention.
Several variants of the invention described above are possible for the man skilled in the art, without departing from the novelty scopes of the inventive idea, as well as it is clear that in the practical embodiment of the invention the various components described above may be replaced with technically equivalent elements.
| Number | Date | Country | Kind |
|---|---|---|---|
| 102022000025026 | Dec 2022 | IT | national |
