FI117024B - The heat pump system - Google Patents

Description

ί HEAT PUMP SYSTEM

The invention relates to a heat pump system as claimed in claim 1.

5

The invention is suitable, for example, for use in paints. The prior art ground parts comprise a compressor, a condenser, a valve, an evaporator, a circulating heating network circulating pump, a refrigerant pipe: temperature and pressure-dependent auxiliary devices such as a refrigerant tank, a filter, a solenoid valve.

15 Known geothermal heat pumps have to make compromises in terms of heating output and efficiency and the production of hot water. The following solutions are known for the heat production of the heating system t.

20

It is known to undersize a heat pump and bring additional resistance. When dimensioned correctly, the example case drops in Scandinavian fluctuating conditions with the best efficiency for outdoor temperatures.

25 -10 ° C to 0 ° C. That is, about half the annual use when the temperature drops below -10oC with an electric resistor. ·· *. additional power share increases and overall efficiency drops <• *

· "· Lid. At temperatures above 0 ° C

• ** required, but the heat pump is then over-powered-

• I

* · * 30 efficiency decreases as the temperature rises.

• · *! · Ί · It is also known to dimension the heat pump to match · «· v. * Fphnnf ^ rvptt ^ so. ai Ιτγ ^ λτλ q-Μί ώ + - λ ha 2 raises its temperature to operating temperature by means of electricity. In this solution, the use of an electric resistor is efficiency.

5 It is also known to operate a heat pump at such a high ratio that the resulting temperature level is sufficient for heating. Increasing the pressure ratio, however, results in a reduction in the compressor load resulting in a heating efficiency of 10 for the heating system, since variable pressure ratio is known in geothermal heat pumps.

It is also known to produce hot hot water by double preheating it from the condenser la 15 by raising it to the operating temperature superheating temperature in which the refrigerant vapor superheat is transferred to the operating solution, however, the above efficiency efficiency pa is unable to control the condensation point. When there is no need for hot water, the hot water in the superheat exchanger rises to the Max. vapor printing is no longer transferred to the hot water, but the point is transferred to the condenser. The superheated steam in the duct, reducing heat exchange in the condenser, was created when heat was supplied to the heating system.

"* ·· 25 • * ·· *] It is an object of the invention to eliminate these drawbacks; * * * * · * 5 to provide a ground source heat pump with heating system * · · * ... · hot water production and hot water in all under conditions of good efficiency <: 30, the transport arrangement according to the invention is characterized by what is set forth in the characterizing claim 1. This method enhances the operation of the condenser to provide efficiency.

In order to achieve the above purpose, according to the invention, the refrigerant is also subcooled to the collector class 1a in a post-heat exchanger. This method improves the performance of the tehc system and improves the efficiency.

To achieve the aforesaid object, the hot water production according to the invention is carried out in a step method, the first step of which is to preheat the hot water from the condenser in a superheat heat exchanger with a flow duct connected to it. The flow channel is controlled by the condensation point location and transferred to the superheater energy reservoir. This method enhances the operation of the nozzle and improves the production of hot water.

More specifically, the invention may be carried out in accordance with the invention. puli is characterized by the following. Geothermal *, ···. the flow rate of the solution from the nozzle to the heating system is controlled. Ground Heat Pump Flowing Cold ΊΙΙ 25 Cooled to Brine in Condenser * ·

The position of the condensation point is adjusted by means of a flow pipe in the superheat heater and in connection with the hot water heater, * * # * ··. *.

* * · 30 The invention will now be described in more detail by way of example: J with reference to the drawings in which 4 4

Fig. 3 shows an alternative superheating transducer assembly connected to the accumulator and Fig. 4 shows a geothermal heat pump according to the invention in conjunction with US. PAT. 6,092,734 to 5 jetties.

A basic component of known geothermal heat pumps in the geothermal heat pump according to the invention is further the flow rate control of the heating system 10 passing through the nozzle 6. The paint according to the invention is the heat exchanger 15 of the condenser 6 and the expansion valve whereby the refrigerant is sub-cooled to the brine circuit 7. The geothermal pump of the invention has a superheat heat exchanger 2 for heating domestic hot water * 15. the superheat heatv is a flow duct 3 connected to the heat accumulator 4, which controls the condensation point

In a ground source heat pump according to the invention, a ground source heat pump; By controlling the flow rate of the 20 solutions entering the system, the condensate of the ground source heat pump When the heating system through the condenser increases its flow rate, the volume of the solution * * '[1' mi power supply requirement is not exceeded. The flow rates can be realized, for example, by means of an adjustable heating mains water pump 5 and a controller, or by using a pump back pipe and valve and a controller. With M 5, a significant improvement is achieved in the geothermal heat pump tea when the geothermal heat pump is connected to the US. PAT. 1 10 In the case of a conventional central heating system, there is no advantage, though not a disadvantage.

The geothermal heat pump according to the invention employs the following method. The cold £ 15 flowing through the underground heat pump is cooled to a brine solution 7 in a condenser heat exchanger 15. The method transfers heat from a temperature of about + 35 ° C to a temperature of about + 5 ° C after process 6. The process achieves the following benefits ; After that, at the same time, the temperature of the collection solution 7:; before evaporator 13. Here's the solution for collection and cold:. ·· *. the temperature difference in the evaporator 13 increases and the heat transfer • heats up, lowering the refrigerant temperature before the * 111 valves also reduces the evaporator operation i • * *** \ the amount of expansion steam. When the heat pump is started • * i * · between the heat exchanger 2 and the expansion valve 12: * ·· * ', the heat remaining at the end of the previous cycle is efficiently utilized by transferring the heat to the collector * »: 30 7. starting from the time when the refrigerant water is preheated from the condenser of the ground source heat pump by the heat from the condenser of the ground heat pump to a temperature of + 35 ° C. In step 2, the water temperature to the actual operating temperature is the so-called. superheating heat 5 2 with superheated refrigerant vapor (approx. + 90 ° C) in hot water. The geothermal heat pump according to the invention is characterized by a superheat heat exchanger 2 therein, already made of two nested copper tubes and used by Joy 2.2 through which the copper tubes are passed. A superheated refrigerant vapor travels inside the cup 2.3 and in the space between the outer tube there is a heating solution which communicates with the accumulator 4.

The method has the following advantages. Hot water

The total energy of 15 is obtained from inverse C

sub-process. The refrigerant vapor superheat is removed before the pre-condenser 6. Thus, the condensation point is before the condenser.

is in the condenser in its entirety as a solution, the change in solution of the heating system being 20 t. The solution in the space between the copper pipes and the heater system in the accumulator 4 can be used to control the position of the sink even when there is no need for hot water and its temperature reaches 9 * ·· "'in the heat exchanger 2 close to its maximum value. accumulator 4. »\ .. 5 refrigerant pipe 2.3 in the heat exchanger 2 2.3. · · * ·· refrigerant pressure in the compressor circuit (no * ·· overcomes the pressure in the heating system and is discharged through a safety valve (1.5 bar); the pressure is 2-3 ·. ***. the system is safe and the refrigerant cannot 7 be located in the upper part of the tank, the flow pipe will bring eg outside the tank.

The superheat heat exchanger may be of any other type 5 having a flow duct 3 acting as a flow duct, the location of the anchor point can be controlled.

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Claims (6)

A heat pump system comprising at least one up circuit {18} which feeds heat to a heating circuit (19), said refrigerant circuit comprising a compressor (1), a compressor control, a condom a solenoid valve (10), an expansion valve (12), a (13) and a pressure switch (17) and in which system c the heating circuit (18) circulating solution is controlled serially through the condenser (6) so that the temperature of the condenser (6) exiting the coolant in the refrigerant circuit is changed by the circulation rate of that <densor> (6). ), in the heating circuit (18 the solution is changed, and which system is provided <15 for heating the operating water intended for superheat inheritance (2), characterized in that the system is provided with a flow channel (3), by means of which flow is superfluous). the superheat heat in superheat heat (2) is removed 2. A heat pump system according to claim 1, characterized; the temperature of the output of the condenser (6), ····. the cooling circuit (19) circulating the refrigerant and the solution circulating in the heating circuit (18) is lowered * * 111 'the circulation rate of the 1 heating circuit in Γ *. the circulating solution is increased by means of a circulating water pump (5) located in the circuit (18). • · »· ♦ · * Heat pump system according to claim 1 or 2, characterized in that the temperature of the refrigerant circulating refrigerant (19) is lowered from the condenser (6). 4. A heat pump system according to any of the preceding veins, characterized by being inside the superheater heating path. there is one part of the refrigerant circuit (19) and one part of the cooling circuit (18), which share between each other that the part of the refrigerant circuit (19) is inside the part of the circuit (18). 5. A heat pump system according to claim 4, characterized; the portion <10 of the media circuit (19) and the portion of the heating circuit intermediate located within the superheat heat exchanger (2) is arranged so that the coolant steam exits the operating water in the operation (2.2) of the superheat heat exchanger (2.2) via the heating circuit's solution 1 6. A heat pump system according to claim 4 or 5, characterized in that the condensation point of the refrigerant steam via the temperature change of the flowing channel (3) is adjusted to the desired position of the condenser (6). I · • · • · «· ···:: · ♦ · ψ ··» *:: ··· • «• · · • ♦ * ··