| CLAIMS 1. A device (1) for metering the heat energy emitted by radiators, convector heaters or the like, particularly for the apportionment of heating and/or conditioning costs, comprising a radiator (2) which is connected, through a respective delivery manifold (3) and a respective return manifold (4), respectively to a duct (5) for delivery of the hot water sent by a boiler (7) to said radiator (2) and to a duct (6) for return of the water in output from said radiator (2) toward said boiler (7), characterized in that it comprises, for said radiator (2), a first meter (8) for the temperature of the water that flows through the respective delivery manifold (3) and a second meter (9) for the temperature of the water that flows through the respective return manifold (4), there being further a flow meter (10) for the water that flows through said radiator (2). 2. The metering device (1) according to claim 1, characterized in that it comprises a plurality of radiators (2) which are connected, through a respective delivery manifold (3) and a respective return manifold (4), respectively to said delivery duct (5) and to said return duct (6), each one of said at least two radiators (2) being associated with the first meter (8) for the temperature of the water that flows through the respective delivery manifold (3) and with a second meter (9) for the temperature of the water that flows through the respective return manifold (4), there being also a flow meter (10) for the water that flows through each one of said at least two radiators (2). 3. The metering device (1) according to one or more of the preceding claims, characterized in that said flow meter (10) is arranged substantially along said return manifold (4) in order to measure the flow-rate of water in output from said radiator (2). 4. The metering device (1) according to one or more of the preceding claims, characterized in that said flow meter (10) is chosen within the group that comprises: - volumetric flow meters; - Venturi flow meters; - turbine flow meters; - ultrasound flow meters; - electromagnetic flow meters; - infrared flow meters. 5. The metering device (1) according to one or more of the preceding claims, characterized in that said delivery manifolds (3) are associated with a respective first valve (11) for adjusting the flow-rate of hot water in input to the respective radiator, said first temperature meter (8) being accommodated within said adjustment valve (11). 6. The metering device (1) according to one or more of the preceding claims, characterized in that said return manifolds (4) are associated with a respective closure valve (16), said second temperature meter (9) being accommodated within said closure valve (16). 7. The metering device (1) according to one or more of the preceding claims, characterized in that said closure valve (16) is associated with said flow meter (10) and has an inverted U-shaped duct (10a) which is connected, through an inlet (10b), to the outlet (4a) of said radiator (2), said inverted U-shaped duct (10a) having, on the opposite side with respect to said inlet (10b), a supply opening (10b) connected to an outlet (4c) which can be open/closed by means of a closure body (17). 8. The metering device (1) according to one or more of the preceding claims, characterized in that said adjustment valve (11) comprises an adjustable thermostatic valve, 9. The metering device (1) according to one or more of the preceding claims, characterized in that it comprises a device (12) for storing the data measured by said first meter (8) for the temperature of the water that flows through said delivery manifold (3), by said second meter (9) for the temperature of the water that flows through said return manifold (4), and by said flow meter (10) for the water that flows through said radiator (2). 10. The metering device (1) according to one or more of the preceding claims, characterized in that it comprises a containment structure (13), which can be positioned at said return manifold (4) and accommodates said flow meter (10) and is connected to said second meter (9) for the temperature of the water that flows through said return manifold (4). 11. The metering device (1) according to one or more of the preceding claims, characterized in that said containment structure (13) comprises said storage device (12). 12. The metering device (1) according to one or more of the preceding claims, characterized in that it comprises means for the removable application of said flow meter (10) on said return manifold (4). 13. The metering device (1) according to one or more of the preceding claims, characterized in that said removable application means are adapted to allow disassembly of said flow meter (10) from said return manifold (4) in order to verify the correct operation of said flow meter (10). 14. The metering device (1) according to one or more of the preceding claims, characterized in that it comprises means for sending the data measured by said first meter (8) for the temperature of the water that flows through said delivery manifold (3) toward said storage device (12). 15. The metering device (1) according to one or more of the preceding claims, characterized in that it comprises means for sending the data stored by said storage device (12) toward a centralized apportionment system. |
CONDITIONING COSTS
5 Technical Field
The present invention relates to a device for metering the heat energy emitted by radiators, convector heaters or the like, particularly for the apportionment of heating and/or conditioning costs. Background Art 0 In many dwelling situations, such as for example condominiums, there are heating systems constituted by a centralized boiler body, which supplies each dwelling unit with the hot water required for example to heat the rooms.
Especially in old-generation systems, for example those with so-5 called rising pipes, ducts for the delivery of the hot water and for the return of the cold water branch out from the boiler body and are connected, by means of unions and interconnection ducts, to the manifolds of each radiator, radiating panel or convector heater.
In order to allow each dwelling unit to pay as a function of the heat0 energy that is actually used, metering devices or heat apportionment devices have long been commercially available which are placed on each radiator and measure and record the heat consumption of each radiator.
Currently known metering devices, however, perform an indirect measurement of heat consumption, since by way of a probe they measure an5 index that is correlated to heat emission: to allow calculation of actual heat consumption, it is necessary to "program" each metering device, or use typical coefficients in cost apportionment, by entering the specific data (number of elements, radiant power for each element/column, et cetera) of the radiator or of the fanless convector heater with which it is associated.0 In this regard it is noted that by using the traditional metering devices described above it is not possible to meter the consumption of fan convector heaters (which operate by forced convection).
The types of metering device briefly described above, despite being used widely, are however not free from drawbacks. First of all, it is evident that the need to enter the specific data of the radiators or convector heaters causes two different types of problem; first of all, the installation technician must pay particular attention in programming, and on the other hand it has been observed that the specific power data provided by the manufacturers are not always reliable. DE 3644966 Al, in the name of Gentischer, discloses a system for measuring heat consumption in a heating system composed of a hot water generator connected by means of pipes to a plurality of radiators.
In this system, each radiator is provided with a thermostatic valve that has a sensor adapted to detect the closed or open state of the valve. Each radiator is further associated with temperature sensors designed to measure the delivery and return temperature. The system described in DE 3644966
Al, however, merely estimates the heat consumption for each radiator, providing the thermostatic valve in such a manner that it can in some way adjust the flow of water that enters the radiator. Although this constructive solution is valid from a conceptual standpoint, it is extremely unsatisfactory from a practical standpoint for various reasons.
First of all, the system performs an indirect estimate of the amount of water that flows through each radiator, since such estimate is based on the measurement, by means of a sensor, of the closure or degree of opening of the thermostatic valve, and on the fact that inside the valve there are pressure adjustment means which, in theory, should adjust the amount of water that passes through the radiator.
It is clearly evident that the precision of the estimate is influenced by several factors, such as correct operation of the pressure adjustment means, and by the tolerances of the mechanical components that define, within the thermostatic valve, the opening or openings for the inflow of the hot water toward the radiator.
In this regard, substantial problems from a constructive standpoint are observed in trying to insert, within the thermostatic valve, further additional components such as the sensor for detecting the closed and open condition and the pressure adjustment means.
Moreover, the inflexibility of application of the system described in
DE 3644966 Al is evident, since it can be used exclusively on radiators or on fanless heat converters, moreover provided with a thermostatic valve.
In some new-generation systems there are instead multiple outgoing and return ducts that extend from the centralized boiler, as besides disclosed in DE 91 1 1971 Ul in the name of Landis & Gyr Betriebs Ag and in EP
0035089 in the name of Aquametro AG. Each pair of ducts is designed to connect the centralized boiler to the radiators of a respective dwelling unit and is provided with respective meters for the delivery and return temperature and for the flow-rate of water sent through the delivery duct.
These systems allow to meter the heat consumption of each dwelling unit, but they, too, have drawbacks, which are constituted for example by the need to use several pairs Qf ducts (one pair for each dwelling unit), with an evident increase in the installation costs of the system.
Moreover, it is evident that this measurement method cannot be used in condominiums with systems using rising pipes. Finally, it is noted that the flow-rate and temperature meters used in these systems have longitudinal space occupations that do not allow to use them at the individual radiators and/or heat converters that have already been installed and positioned for a long time.
Disclosure of the Invention The aim of the present invention is to solve the problems and obviate the drawbacks noted above, by providing a device for direct metering of the heat energy and/or refrigerating energy emitted by radiators, convector heaters or the like, particularly for the apportionment of heating and/or conditioning costs, that is considerably easier and more practical to use than known types of metering device currently in use.
Within this aim, an object of the invention is to provide a device for metering the heat and/or refrigerating energy emitted by radiators, heat convectors or the like that is easy to install and has extremely low operating costs. Another object of the invention is to devise a metering device that can be used to apportion the heat energy of fan convector heaters.
A further object of the invention is to provide a device for metering the heat energy and/or refrigerating energy emitted by radiators, convector heaters or the like in which reprogramming operations are not necessary in case of replacement of the radiator, convector heater or the like and which allows practical installation without particular technical interventions on the system.
Another object of the invention is to propose a device for metering the heat energy and/or refrigerating energy emitted by radiators, convector heaters or the like that has a competitive manufacturing cost, so that its use is advantageous also from an economic standpoint.
This aim, as well as these and other objects that will become better apparent hereinafter, are achieved by a device for metering the heat energy and/or refrigerating energy emitted by radiators, convector heaters or the like, particularly for the apportionment of heating and/or conditioning costs, according to what is provided in claim 1.
Brief description of the drawings
Further characteristics and advantages of the invention will become better apparent from the following detailed description of some preferred but not exclusive embodiments of a device for metering the heat energy and/ or refrigerating energy emitted by radiators, convector heaters or the like, particularly for the apportionment of heating and/or conditioning costs, according to the invention, illustrated by way of non-limiting example in the accompanying drawings, wherein: Figure 1 is a schematic view of a first embodiment of a metering device according to the invention;
Figure 2 is a view of a second embodiment of the metering device;
Figure 3 is a view of a practical embodiment of the metering device;
Figures 4 and 5 are respectively a sectional view and a front view of a closure valve associated with a water flow-rate measurement device. Ways of carrying out the Invention
In the exemplary embodiments that follow, individual characteristics, given in relation to specific examples, may actually be interchanged with other different characteristics that exist in other exemplary embodiments. Moreover, it is noted that anything found to be already known during the patenting process is understood not to be claimed and to be the subject of a disclaimer.
With reference to the figures, the present invention relates to a device, generally designated by the reference numeral 1 , for metering the heat and/or refrigerating energy emitted by radiators, convector heaters, radiating panels or the like, particularly for the apportionment of heating and/or conditioning costs.
The metering device 1 comprises a radiator 2, which is connected, by means of a delivery manifold 3 and a return manifold 4, respectively to a duct 5 for the delivery of the hot water sent by a boiler 7 to the radiator 2 and to a duct 6 for the return of the water in output from the radiator 2 toward the boiler 7.
According to the present invention, the metering device 1 comprises a first meter 8 for the temperature of the water that flows through the delivery manifold 3 and a second meter 9 for measuring the temperature of the water that flows through the return manifold 4 of the radiator 2.
There is also a meter 10 for the flow-rate of water that flows through the radiator 2,
Conveniently, as shown in Figure 1 , the metering device 1 comprises at least two radiators 2 or, advantageously, a plurality of radiators 2 or the like, each of which is associated with the first meter 8 of the temperature of the water that flows through the delivery manifold 3, to the second meter 9 of the temperature of the water that flows through the return manifold 4 and to a meter 10 for measuring the flow-rate of the water that flows through the radiator 2.
Conveniently, the radiators 2 can belong to different dwelling units
(for example of the same condominium building) which are connected, by means of the delivery manifold 3 and the return manifold 4, to the boiler 7, which is typically constituted by a so-called centralized boiler for example by means of rising pipes.
With reference to the diagram shown in Figure 1, the flow meter 10 is arranged substantially at the return manifold 4, so as to measure the water flow-rate in output from the radiator 2.
Of course, nothing forbids the provision, as shown schematically in Figure 2, to arrange the flow meter 10 for the water that passes through the radiator 2 along the delivery manifold 3.
The flow meter 10 is advantageously chosen within the group that comprises:
- Venturi flow meters; - volumetric flow meters;
- turbine flow meters;
- ultrasound flow meters;
- electromagnetic flow meters;
- infrared flow meters. It has been found that the use of so-called static flow meters is particularly advantageous.
According to a preferred embodiment, the delivery manifolds 3 are associated with a valve 11 for adjusting the flow-rate of hot water in input to the respective radiator 2. Specifically, the first temperature meter 8 is accommodated within the adjustment valve 11,
Advantageously, the return manifolds 4 in turn are associated with a respective closure valve 16, commonly referenced by the expression lockshield valve, for the flow-rate of water in output from the radiator 2. In case of heat convectors it will not be necessary to install a thermostatic valve, but it will instead be possible to simply provide a temperature acquisition probe trap.
In this case, the second temperature meter 9 is accommodated inside the closure valve 16. It is convenient for the adjustment valve 11 to be constituted by an adjustable thermostatic valve, designed to control the flow of the delivery manifold 3 in order to allow to adjust, according to requirements, the temperature of the room and therefore of the water that circulates within the radiator 2. The first meter 8 for the temperature of the water that flows through the delivery manifold 3 can advantageously be accommodated within the adjustable thermostatic valve.
In order to allow the acquisition, and consequently the processing, of the data related to the heat consumption of each radiator 2, it is advantageous for the metering device 1 to have a device 12 for storing the data measured by the or each first meter 8 for the temperature of the water that flows through the delivery manifold 3, the data measured by the or each second meter 9 for the temperature of the water that flows through the return manifold 4, and the data measured by the or each flow meter 10 for the water that flows through the radiator 2. The storage device 12, which can of course be interfaced with per se known data processing systems, allows to measure directly, continuously or at predefined time intervals, the heat consumption of the individual radiator 2. With reference to the embodiment shown in Figure 3, the metering device 1 comprises a containment structure 13, which can be positioned at the return manifold 4.
The containment structure 13 accommodates internally the flow meter 10 and is connected to the second meter 9 for the temperature of the water that flows through the return manifold 4, so as to be able to acquire directly therefrom the measured data.
Conveniently, the containment structure 13 comprises internally the storage device 12.
The metering device 1 further has means 14 for sending the data measured by the first meter 8 for the temperature of the water that flows through the delivery manifold 3 toward the storage device 12.
The storage device 12 is further associated with means for sending the stored data to a centralized apportionment system; in this regard, it is convenient for the storage device to be provided with power supply means which allow both to store the data and to send such data toward the apportionment system,
Preferably, such sending means 14 can be constituted by a data transmission cable or by wireless transmission means. In this case, the first meter 8 for the temperature of the water that flows through the delivery manifold 3 must be associated with a battery that allows data transmission.
Such battery might be associated with automatic recharging devices capable for example of utilizing the temperature variation to recharge the battery.
The containment structure 13 can thus be associated with a data transmission antenna 15 and optionally with a display device adapted to allow the user to check at any time the heat and/or refrigerating consumption.
According to an aspect of the present invention, the metering device 1 comprises means for the removable application of the flow meter 10 on the return manifold 4 or on the delivery manifold 3.
In particular, the removable application means are adapted to allow disassembly of the flow meter 10 and optionally of the storage device 12 associated therewith from the return manifold 4 in order to check periodically (for example every five years) the correct operation of the flow meter 10: this allows to obtain certifications (for example, the MID - Measuring Instruments Directive - certification) capable of giving assurance to the user as to the correct operation of the flow meter 10.
Conveniently, as clearly shown in Figures 4 and 5, the flow meter 10 is associated with a closure valve 16, also known as lockshield valve. In particular, the closure valve 16 has a space occupation, and in particular a longitudinal space occupation, that is substantially similar to the space occupation of the closure valves 16 that are currently used, so as to allow use of the metering device 1 according to the invention without the need to intervene on the systems that have already been installed. Specifically, the flow meter 10 has an inverted U-shaped duct 10a connected, through an inlet 10b, to the outlet 4a of the radiator 2.
On the opposite side, the inverted U-shaped duct 10a leads to a supply opening 10b which is connected, conveniently by means of a connecting portion 10c, to an outlet 4c, which can be opened/closed by means of a closure body 17 that can be operated, for example with a screwdriver, by the user.
In particular, the closure body 17 comprises a flow control ball 17a, which is designed to be moved along a movement direction 200 in order to shift between a flow blocking condition (in which it closes the outlet 4c) and partial and/or total opening conditions, in which the outlet 4c is IO connected to a respective discharge opening 4b that leads into the return manifold 4.
Advantageously, the closure valve 16 has three discharge openings 4b, which are distributed with a mutual angular spacing of 90° with respect to the movement direction 200,
Depending on the mutual position between the radiator 2 and the return manifold 4, two of the three discharge openings 4b are blocked.
Conveniently, the inverted U-shaped duct 10a can be connected, at the inlet 1 Ob and at the supply opening 1 Ob, and by way of connecting means typically constituted by threaded nuts 18, to the closure valve 16 so as to be able to remove, if necessary, the inverted U-shaped duct 10a.
The operation of a device 1 for metering the heat energy and/or refrigerating energy emitted by radiators, heat convectors or the like, particularly for the apportionment of heating and/or conditioning costs according to the invention, is evident from what has been described above.
In this regard, it has been observed that the metering device 1 allows to measure the emitted heat energy of each radiator 2 very precisely and so as to allow to use substantially the first adjustment valves 1 1 that are currently commercially available and inside which the first temperature meter 8 is to be accommodated.
The provision of a flow meter 10 that is external to the first adjustment valve 11 and advantageously arranged along the return manifold 4 allows to perform an actual direct measurement, not an indirect estimate, of the flow of water that passes through the radiator 2. Moreover, this system allows to measure the heat emitted by radiators and/or by convectors, both natural and of the type with air forced by using fans, and the heat emitted (or the refrigeration units consumed) by heating and conditioning systems in general.
If one wishes to meter the calories/refrigeration units in heat convectors provided with a fan, it is in fact possible to simply associate the first temperature meter 8 within the probe trap along the delivery manifold 3 without the need to use thermostatic valves.
Moreover, thanks to the flexibility of the metering system 1 according to the invention, it is possible to meter apartments or condominiums in which mutually different heating/cooling means are installed.
Moreover, the possibility to disassemble from the radiator 2, conveniently in a detachable manner, the flow meter 10 (and optionally the storage device 12 associated therewith) allows to periodically check correct operation. In practice, the dimensions may be any according to requirements.
All the details may further be replaced with other technically equivalent elements.
The disclosures in Italian Patent Application No. VR2009A000087 from which this application claims priority are incorporated herein by reference.
Where technical features mentioned in any claim are followed by reference signs, those reference signs have been included for the sole purpose of increasing the intelligibility of the claims and accordingly such reference signs do not have any limiting effect on the interpretation of each element identified by way of example by such reference signs.