FR2516639A1 - Air conditioning and hot water solar heater - has solar panel coupled with heat pump with hot air ducting - Google Patents

Abstract

The building heater solar panel has separate air and water circuits. The water circuit supplies a heat exchanger in the domestic hot water circuit (d.h.w.) and then discharges to a hot water accumulator from where it is pumped back into the circuit. The d.h.w. is also heated by a standby fuel-fired heater. The air ducting uses warm air from the solar panel and, by use of bypass dampers, the air flows can be optimised. The input fan supplies the building. Air is extracted by the fan and/or recirculated in the duct. A heat pump is interposed between the exhaust and recirculation ducts. An air-to-water heat exchanger is also incorporated in the d.h.w.cylinders.

Description

 The present invention relates to air conditioning and domestic hot water supply facilities. The term air conditioning is taken in the broad sense because this invention, the fruit of a global approach to needs, includes the supply of domestic hot water, temperature regulation (heating and refrigeration), the supply of fresh air, extraction selection of stale air and the possibility of using the system in frost protection. In addition, this installation by the use of a single injection sheath (G1) and a single extraction sheath (G3), makes it possible to ensure the flows of air injected and extracted from the premises all the treatments likely to be necessary (filtration, chemical neutralization, disinfection, ionization, irradiation, humidification, drying, ...).

 The main source of energy for heating and supplying domestic hot water is solar energy.

 The necessary supplement in times of solar supply shortage can be provided by any energy source (solid, liquid or gaseous fuels, electricity, district heating, ...>.

 Electrical energy is used to ensure the flow rates of the various fluids, drive the heat pump and regulate the assembly.

 Previous solar heating and domestic hot water production systems often use flat air or liquid collectors whose yields are particularly low or zero by diffuse or low-incidence radiation and / or by low outside temperatures. In winter, diffuse radiation usually provides almost 50% of the solar energy and low temperatures are the source of our energy needs. Previous approaches propose either to use complex and expensive sensors, or to use the sensor or the heat transfer fluid as the cold source of a heat pump. None of these solutions is sufficiently efficient to be undoubtedly economical today. The use of heat pumps finding their cold source in the ambient air or in the solar supply, provides a certain gain in KWH, unfortunately, at saving thermal energy is associated with spending electrical energy. In addition, none of these systems is capable of simply providing all the air conditioning needs and their integration into already existing premises is often a problem.

 To this end, the installation according to the present invention is characterized by its particularly simple and efficient architecture, by the use of a sensing surface with original structure, by a hydraulic loop using two different flow rates, by the control of three flow rates d air of a different nature (supply of new air, recirculation and extraction of vitiated air) and by the integration of a heat pump between recirculation and air extraction flows. See plates 1 and 2 attached.

 Collector: The solar energy-collecting surface uses as heat transfer fluids, separately or simultaneously, a liquid with high thermal capacity and the outside air. The liquid circulation absorber is ventilated by an external air flow taken from the lower section of the sensor. The liquid flow ensures the accumulation of solar energy, the gas flow ensures the supply of fresh air. In a particularly advantageous embodiment, the collector acts as a pan roof and is constituted in the following manner, starting from inside the premises: a suitably insulated box frame; covered with a sheet of polished aluminum, itself covered with a transparent plastic film to prevent its oxidation; spacer profiles to allow the lower ventilation of the absorber and its maintenance; the absorber with circulation of liquid, absorbent face on the sky side, reflecting face on the frame side; spacer profiles to allow upper ventilation of the absorber and maintenance of the glazing. A temperature sensor Ti controls the establishment or stopping of the liquid flow according to the temperature T2 of the accumulator so as to ensure an always positive yield. In times of solar energy shortage, all the contribution of fresh air is taken through the sensor, during an abundance period, the sensor air flow will vary as required between the nominal value of the fresh air flow and zero. By night operation, the sensor air flow will also be canceled so as not to obtain negative efficiency.

 Hydraulic loop: From an accumulator, the circulation of the fluid is ensured by one or two pumps through the absorber then through an exchanger of domestic hot water supply before returning to the accumulator. In times of caloric shortage, detected by a low temperature T2, the flow rate used is high, in order to limit the temperature of the absorber and thus improve the yield. During a period of caloric abundance, detected by a high temperature T2, the flow rate is low, which makes it possible to have a high sensor outlet temperature.

The supply of domestic hot water is better ensured, the pump consumption is reduced, the degradation of the output being then without consequence. Protection against freezing can be ensured either by emptying the sensor when the pump is stopped, or by using a coolant with a low freezing point. In a particularly efficient embodiment, which is that shown in boards 1 and 2 attached, the accumulator is a water tank, insulated, partially buried in the basement of the premises and protection against freezing is ensured by emptying from the sensor to the pump stop (solenoid valve H).

Fresh air flow: In times of need for solar supply, the air sucked in at the base of the sensor by the fan V1, passes through valve C, passes through an exchanger integrated in the accumulator, passes through mixing valve D, is optionally heated by the auxiliary heating system and then treated (F) before being injected into the premises. Valve
Its function is to avoid using the sensor in negative redation. In night operation, in clear skies, the losses can exceed the gain ensured by the recovery of the roof losses. For a given threshold, outdoor ambient temperature minus absorber temperature (TO - Tel), valve C switches, cancels the collector air flow and the air supply is then at ambient temperature TO. When the solar gains are overabundant the air flow upstream of the accumulator is limited by the mixing valve D in favor of an outside air supply at room temperature TO. The supply of fresh air is then ensured at a constant flow rate but at a regulated temperature between the downstream accumulator temperature and the ambient temperature TO.

 Air recirculation flow (G2): When there is a significant demand for heating power, the fresh air flow determined according to the characteristics of the premises and their use, may not be sufficient to provide at a moderate temperature the heating power required. An air flow is then recirculated thanks to the opening of valves A or B and the change in speed of the fan Vi. Valve A is used if the accumulator temperature T2 is sufficient to ensure an energy supply, otherwise, it is valve B which opens, the fan Vi ensuring in each of these cases a flow rate equal to the flow rate fresh air increased by the recirculation flow. Upstream, the recirculation flow has heated up by passing through the condenser of the heat pump.

As for the fresh air flow, the backup is supplied downstream as required. When the setpoint temperature TC is exceeded due to a high outside temperature and / or high solar radiation, the supply of fresh air is then ensured by the mixing valve D which cancels the air flow upstream of the accumulator and only admits an outside air flow at room temperature TO. If refrigeration is necessary, valve B is open and the recirculated air flow, after passing through the evaporator of the heat pump, is superimposed on the fresh air flow to cool the premises. As with heating, when valve B is opened, there is a change in fan speed V1 which then ensures the flow of fresh air plus the recirculation flow.

 Stale air extraction flow (G3): A permanent stale air extraction flow is associated with the V2 ventilator. Depending on the destination of the premises, these two flow rates can be modulated so as to maintain in the premises, with respect to atmospheric pressure, a low depression, zero differential pressure or a slight overpressure. In times of solar supply shortage, the extraction flow yields its calories to the heat pump evaporator. When refrigeration is required, the extraction flow will draw calories from the heat pump condenser. All the extracted air using only a single duct (G3) its possible treatment (F) before rejection is easy.

 Heat pump: It works between the extraction (G3) and recirculation (G2) flow rates whose temperatures are approximately equal and constant which allows it to be permanently available and have a good coefficient of performance. By switching the extraction and recirculation ducts at the exchangers or by switching the exchanger conduits or by reversing the thermodynamic cycle, the heat pump allows refrigeration.

 Frost protection operation: The hydraulic loop, the heat pump, the hot water and heating backup as well as the exhaust fan V2 are deactivated. Valves A and B are closed, valve D is in the open air accumulator position and only the control amplifier, valve C and fan V1 remain active in the fresh air supply regime.

 The contribution of the sensor used as a simple air sensor associated with the exchanger integrated in the accumulator is sufficient to ensure the maintenance of frost while renewing the air in the premises.

 Heating and domestic hot water backup: Two installations are shown, the first uses a centralized thermal backup unit (PL 1/3), the second (PL 2/3) dissociates the heating backup and the supply of 'hot water. In these two installations, for the auxiliary heating energy, the gas was chosen for its low cost and the ease of regulating its use. In the second installation, the back-up energy for domestic hot water is electricity for its ease of implementation and its very high job security.

It is clear that, for these two installations, any other additional energy source can be used by simple adaptation.

 PL 1/3: This installation brings together in a single reserve of hot water, carefully insulated, the auxiliary heating and domestic hot water system. The gas flow rate is regulated by a valve so as to keep the temperature T3 of the balloon constant. Domestic hot water is always available. The water inlet connection of the boiler exchanger is done at mid-height in order to favor the solar contribution by the exchanger associated with the collector hydraulic loop.

This solar heat exchanger works by thermosyphoning, its water inlet connection is made at the lower part of the reserve in order to work at the lowest possible temperature, this is reinforced by stratification partitions integrated in the reserve . Heating is provided by the air / water exchanger immersed in the upper part of the reserve; the fresh air flow rate, possibly reinforced by the recirculation flow rate, is heated as required by more or less significant bypass controlled by the regulating valve E.

This valve is controlled by the regulating amplifier as a function of the room temperature setpoint (TC) and the temperature prevailing there (T4). The outside temperature (TO) intervenes only in the control loop for anticipation and damping.

PL 2/3: This installation retains the electrical back-up for the
Supply of domestic hot water. Maintaining the temperature of the tank (T5) is optional. The solar heat exchanger works by ther wosyphonllage its connection is made to the lower part of the tank in order to work at the lowest possible temperature; this is supported by stratification partitions integrated into the balloon.

For the additional heating, the fresh air flow, possibly reinforced by the recirculation flow, is heated as required by a hot air generator whose gas flow controlled by the valve R is controlled by the control amplifier. as a function of the room temperature setpoint (TC) and the prevailing temperature (T4). The outside temperature TO intervenes only in the control loop for anticipation and damping.

 Regulation of the assembly: see PL 3/3 - A regulation amplifier manages the entire system from the display of the set temperature (TC) and temperature information provided by the TO, Ti, T2 and T4 probes . In the installation according to PL l / 3 the temperature maintenance system of T3 is independent as well as in the installation according to PL 2/3 for the maintenance of T5e It is clear that according to the needs of the moment are used in the order, the solar contribution, the heat pump then the additional heating. Conversely, it is only after having positioned the mixing valve D in the open air at room temperature that the heat pump operates according to the refrigeration needs. Manual switching selects the different operating modes: refrigeration, ventilation, frost protection and heating.

Claims (5)

R E V E N D I C A T I O N S  10 - Installation of air conditioning of premises and production of sanitary hot water using mainly as energy source solar energy and suitable to use as thermal backup any energy source (solid, liquid or gaseous fuels, electricity, district heating or any centralized moderate temperature energy supply network).  This installation is characterized in that it comprises - a solar energy-collecting surface using as heat transfer fluids separately or simultaneously a liquid with high thermal capacity and the outside air. - a two-flow hydraulic loop provided either by a double-speed pump or by two pumps mounted in parallel and delivering simultaneously or separately. In times of solar supply shortage, the accumulator temperature (T2) is low, the flow used is important. In times of abundance of solar gain (high T2) the flow used is low. - two pneumatic valves (C) and (D) located respectively upstream and downstream of the accumulator. Associated with the drair sensor sample their function is to ensure a constant air renewal flow taking into account the possibilities of the system and the thermal needs of the premises. - two pneumatic air recirculation valves (A) and (B) located respectively upstream and downstream of the accumulator. This recirculation air flow (G2) provided by the fan (VI) allows either by the upstream valve (A) the destocking of the accumulated solar energy, or by the downstream valve (B) thermodynamic recovery of calories from l extract air or refrigeration (PAC). Furthermore, this flow rate which is superimposed on the fresh air flow rate makes it possible to provide the required heating power without reaching high temperatures in the injection sheath (Gl). - a heat pump (PAC) whose exchangers are located in the recirculation (G2) and air extraction ducts (G3). The stale air extraction rate is provided by the fan (V2).  2) - Installation according to claim l characterized in that it comprises a solar energy-absorbing surface using separately or simultaneously a liquid with high thermal capacity and the outside air. The liquid flow is intended to ensure the accumulation of solar energy, the gas flow provides the supply of fresh air. In a particularly interesting embodiment, the collector acts as a pan roof and is constituted in the following manner starting from inside the premises: a suitably insulated frame; covered with a thin sheet of polished aluminum, itself covered with transparent plastic to prevent oxidation; spacer profiles to allow the lower ventilation of the absorber and its maintenance of the liquid-flow absorber on the absorbent side, sky side, reflecting side on the frame side; spacer profiles to allow upper ventilation of the absorber and maintenance of the glazing.  30 - Installation according to claim l, characterized in that the air renewal flow is established, by the sensor or a valve (C), upstream of the solar energy accumulator and thus the integrated exchanger in it makes it possible to supply calories to the air flow which, by decreasing the temperature of the accumulator improves the capture efficiency.  40 - Installation according to claim 1 characterized in that it comprises an admission valve (C) located downstream of the sensor and upstream of the accumulator. From an ambient temperature (TO) minus absorber temperature (T2) threshold, this valve cancels the sensor air flow and the supply of fresh air is at ambient temperature, which avoids using the sensor in negative performance with weak or zero radiation.  50 - Installation according to claim 1 characterized in that it comprises a mixing valve (D) whose first upstream connection is located downstream of the accumulator and the second is a tap of outside air. This valve allows an approximately constant flow of fresh air to regulate the temperature varying between the accumulator downstream temperature and the outside ambient temperature (TO).  60 - Installation according to claim 1 characterized in that it comprises a mixing valve (E, PLl / 3) associated with an exchanger integrated in a source of energy at constant temperature. The downstream connection is located on the air injection duct, the first upstream connection channels the air flow to the exchanger, the second directly in the injection duct. This arrangement allows the flow of fresh air, possibly reinforced by the recirculation flow between modulated in temperature at approximately constant flow.