FR2474149A1 - Recuperation of heat from heat pump compressor - uses heat exchanger in oil sump to heat ventilator refrigerant - Google Patents

Abstract

The heat pump comprises a compressor (10) and a condenser (11), heating an auxiliary water circuit (20). It has an expansion valve (12) and an evaporator (13) cooling the air in a ventilation system (2,3,4). An additional heat exchanger (15) is installed in the oil sump of the compressor. The expanded refrigerant flowing from the expansion valve (12) to the evaporator first passes through a compressor sump heat exchanger (15) and recovers a proportion of the electrical and mechanical energy dissipated as heat by the compressor.

Description

The invention relates to a device for recovering the calories dissipated by a compressor of a heat pump of the type used mainly for heating homes and domestic water.

Heat pumps generally include a closed refrigerant circuit on the path of which are arranged a cold evaporator or exchanger, a compressor, an expansion valve and a hot condenser or exchanger, these elements making it possible to draw calories from an ambient medium and to return to a heat transfer fluid. The ambient medium can for example consist of the stale air extracted from the housing by mechanical ventilation and the heat transfer fluid by water.

We know that we can plotted on an enthalpy diagram, the e-solution of the refrigerant during its passage in the various organs mentioned above: - the fluid in the vapor state enters the compressor at low pressure, - comes out at high pressure: with increase in enthalpy, - cools then condenses according to a high pressure isotherm in the condenser with reduction in enthalpy, - is relaxed according to an isenthalpus by the expansion member, - then vaporizes according to a low pressure isotherm in the evaporator with enthalpy increase and finally enters the compressor for a new cycle. The calories are therefore taken from the ambient medium by evaporation of the refrigerant in the evaporator and then returned to the coolant by condensation of said refrigerant in the condenser.

The increase in enthalpy in the compressor is provided by mechanical work which causes losses which are of electrical origin (motor winding) and mechanical origin (piston, cylinder, valve). In devices such as heat pumps which aim to save energy, this additional resource must not be neglected and it is therefore sou habitable to be able to recover these calories to improve the efficiency of the installation.

These calories can be recovered directly by the refrigerant in the gaseous state which circulates in the compressor, but this solution encounters certain limits due to the fact that this causes an increase in the temperature of the vapors sucked in by the compressor, also called overheating. overheating at the compressor intake conditions the temperature of the discharge vapors, which is limited for reasons of longevity of the refrigeration compressor, in particular when it is a hermetic type compressor. refrigerants can give rise at high temperature to acids which attack the metallic parts of the refrigerant circuit and cause either a mechanical blockage of the compressor, or destruction of the insulation of the windings of the electric motor driving said compressor.

Another solution consists in recovering the calories from the compressor casing by forced ventilation of said compressor to cause a noticeable lowering of the temperature of the burnt gases and a transfer of the calories thus recovered to the evaporator of the heat pump. However, this device leads to a rather complex design of the ventilation circuit and multiplies the heat exchanges between the different fluids, and in particular leads to oversizing of the evaporator.

A third solution consists in directly cooling the oil contained in the compressor casing. This oil is circulated in the compressor mechanism thanks to a suitable pump. It heats up due to electrical and mechanical losses from the engine and compressor. To cool this oil, you can conventionally pass the refrigerant during condensation through a small oil cooling tube located at the base of the compressor. But that obliges to have the condenser in two parts with an entry and an Intermediate output of refrigerant which increases the cost price of the device.

Water cooling can also be ensured by using a water circuit in parallel with the condenser. However, this system can be dangerous when starting up in cold water. Indeed, it risks creating a cold point in the cooling circuit at the level of the compressor and causing an accumulation of liquid refrigerant, which causes liquid to start time.

The invention makes it possible to avoid these drawbacks and aims to recover in a better way the electrical and mechanical losses of the compressor therefore to improve the total performance in May n keeping the operating regime of said compressor within limits ensuring its longevity , in particular with regard to the temperatures of the discharged gases.

According to the invention, the refrigerant which circulates in a closed circuit comprising the evaporator, the compressor, the expander and the condenser, undergoes after its expansion a beginning of evaporation caused by the heat produced by the electrical and mechanical losses. compressor.

Other characteristics and advantages of the invention will appear more clearly on reading the following description with reference to the accompanying drawings which represent - Figure 1: a schematic view of a refrigeration circuit of a
heat pump according to the invention.

- Figure 2: an enthalpy diagram illustrating a frico cycle
rific with and without compressor cooling.

FIG. 1 shows a heat pump designated as a whole by the reference 1 comprising a compressor 10, a hot exchanger or condenser 11, a pressure reducer 12 and a cold exchanger or evaporator 13, these members being traversed in the direction indicated by the arrows with a refrigerant and constitute the refrigeration circuit proper of the heat pump.

A fan 2 ensures the circulation of the flow of extracted air forming the hot source, from a sheath 3 to the evaporator 13 then in the sheath 4. The condenser 11 is of the water condenser type, the water or heat transfer fluid constituting the cold source for the heat pump and supplying in a closed loop a use circuit 20 for heating the housing and / or a domestic hot water production tank.

According to the invention, the refrigeration circuit downstream of the expansion valve 12 in the direction of circulation of the refrigerant does not end directly at the evaporator but follows a diverted path 14 towards a small exchanger tube 15 disposed in the oil to the base of the bell of the compressor 10 so that said refrigerant begins to evaporate thanks to the calories provided by the hot oil and consequently energetically cools this oil.

We will now describe the refrigeration cycle of the refrigerant by referring to the enthalpy diagram shown in Figure 2. This diagram shows the enthalpies in Kcal / kg and the absolute pressures on the ordinate. It is known that the changes of state of the refrigerant can be identified on such a diagram by a curve Ade liquid / vapor saturation.

In the region included in the concavity of this curve, the fluid is in a 1-phase aphasic state (condensation or evaporation) to the right of the curve, in the range below the critical temperature for which the fluid becomes noncondensable, the fluid is in the gaseous state; to the left of the curve, the fluid is in the liquid state.

In this diagram, the refrigerant cycle without compressor cooling can be represented schematically by the outline a, b, c, d, e, f, and a. The state of the fluid at the inlet of compressor 10 is indicated by point a (superheated steam).

The vapor is compressed up to b and consequently leaves the compressor in the highly overheated state; it cools in the condenser 11 under the action of the cold source until it reaches the saturated vapor curve A (point c) then condenses at constant temperature until complete transformation into saturated liquid in d; this liquid is slightly sub-cooled by the cold source until it leaves the condenser at e corresponding to the introduction into the regulator 12.

The fluid then returns to the bipnasic state (expansion e, f), evaporates in the evaporator 13 (f, a) under the active principle of the hot source and is reintroduced into the compressor 10 in the light state. highly overheated in a.

When the refrigerant circulates in the small exchanger tube 15 located in the hot oil of the compressor 10, downstream of the expansion valve 12, it undergoes an evaporation shutter (f - f1) of the original fluid with recovery of the losses if although the vapors at the inlet and outlet of the compressor (a1 - b1) are cooled. This is clearly indicated on the diagram in Figure 2 where points a1 and bi at the inlet and outlet of the compressor are on isotherms of temperature B lower than the isotherms corresponding to points a and b when there is there is no cooling of the compressor which results for the heat pump as a whole, by an additional possibility of evaporation of the friyorigenic fluid and consequently makes it possible to increase the power available on the evaporator and on the condenser.

In addition, this dispos4tion makes it possible to recover in a better way the electrical and mechanical losses therefore to improve the efficiency while maintaining the operating range of the compressor within acceptable limits ensuring its longevity, in particular with regard to temperatures. repressed vapors. In addition, since this cooling of the compressor takes place only when the heat pump is in operation, there is no risk of there being stopped, the creation of a cold point which would cause the accumulation of refrigerant in the compressor bell
This arrangement also makes it possible to avoid complicated circuits for ventilating the compressor and to reduce the dimensions of the heat pump.

The description relates to a preferred embodiment of the invention, variants which can be envisaged without departing from the scope of this invention

Claims (1)

DREAM 5 DICATI 0 NS 1 / Device for recovering the calories dissipated by a compressor of a heat pump used for central heating and / or the production of domestic hot water and including a railroad circuit of refrigerant on the route which are arranged a cold evaporator or exchanger, a compressor, a pressure reducer and a hot condenser or exchanger characterized by the fact that the refrigerant undergoes after its expansion an upright evaporation caused by the heat produced by the electrical and mechanical losses of the compressor . 20 / Device according to claim 1 characterized in that that the refrigerant circulates downstream of the expansion valve (12)  in a diverted route t14) to a small tube-exchanger  (13) placed in the oil at the base of the compressor bell (10).