SE528734C2 - Cooling system e.g. air conditioner has expansion valve membrane and valve mechanism which control opening of expansion valve based on amount of liquid vaporized in signal channels - Google Patents

Abstract

A control device (7A) which is arranged to receive liquid from a condenser (4), includes an outlet to a condensate channel (9) connected to an expansion valve (17A) and an inlet to the signal channels (6,10). A heat exchanger (11) vaporizes liquid present in the signal channels. An expansion valve membrane (12) and a valve mechanism (13) which are connected to the signal channels, control the opening of the expansion valve based on the amount of liquid vaporized in the signal channels. An independent claim is included for method for controlling cooling systems.

Description

self-acting, and they are large and bulky with a valve connected to a float for controlling the entire amount of condensate.

US-A-3,388,558 and EP-A-0,939,88O disclose systems with thermostat valves which, by means of electric heating of the thermodel of the system, actuate a diaphragm which opens a valve when the pressure increases. Nor are these systems self-acting, since the control pulse consists of electrical resistors for heating a bulb with an external modulating control signal for heating.

US-A-5,156,017 discloses a temperature controlled system which controls the flow by means of the temperature difference between the subcooling of the outgoing condensate and the condensing temperature.

However, these controls do not allow full utilization of the condenser surfaces as a subcooling loop is required to control the outgoing condensate.

US-A-3,367,131 discloses a system with a traditional thermostatic expansion valve which regulates the difference between evaporation temperature and superheated gas after evaporator by means of impulses from a gas-filled, thermosensitive sensing body.

The system is controlled via superheating of gas after evaporation, which means that the control impulse for the expansion valve can have a negative effect on the temperature difference between refrigerant and heat-emitting medium.

US-A-4,267,702 discloses systems with a pressure sensing valve which completely or partially shuts off the liquid supply depending on the pressure difference between operation and stop. However, the systems do not regulate the condensate outflow due to uncondensed gas. The control function is not affected by the condensate quality.

There is thus a need for a system which in a simple and flexible way solves the problems with the above-mentioned systems. Disclosure of the Invention An object of the present invention is to solve the problem that gas present in condensate causes unnecessary power losses.

Another object of the invention is to solve the problem of controlling the liquid flow from the condenser so that uncondensed gas does not pass past the condenser control.

According to a specific embodiment, an object of the invention is to solve the problem of recovering subcooling heat without reducing the condenser power of the condenser.

According to a first, preferred embodiment, an object of the invention is to solve the problem of regulating the flow of liquid by means of pressure impulses to already known valve constructions.

According to an alternative embodiment, an object of the invention is to provide a solution to the problem of controlling the liquid flow in cooling system / heat pump system with a float valve for signal flow to an expansion valve.

A specific object of the invention is to control the liquid flow in such a way that the system is self-acting without the need for external, for example electrical control means.

Finally, it is an object of the invention to solve the problem of providing an evaporator surface with refrigerant without the need for superheating of the suction to control the flow.

Said object is achieved by means of a cooling and heating device as stated in the characterizing part of claims 1 and 8 and associated subclaims.

The invention also relates to a method for controlling a cooling or heating device which is substantially characterized by the characterizing part of claims 13 and 16 and associated subclaims. BRIEF DESCRIPTION OF THE DRAWINGS The invention will in the following be described in a non-limiting manner and for illustrative reasons with reference to the accompanying figures in which: Fig. 1 shows a control system according to a preferred embodiment of the present invention, Fig. 2 shows a device for detecting gas bubbles according to the present invention, Fig. 3 shows a heat exchanger device according to the present invention, Fig. 4 shows a control system according to an alternative embodiment according to the present invention, and Fig. 5 shows a float device according to the present invention.

Detailed description of the invention Figure 1 shows a system for heating, cooling or freezing systems. The system consists of: pipes containing refrigerant (not shown), 17 A, a compressor 2, a condenser 4, an expansion valve an evaporator 20, a liquid separator 24, an oil return device 21, an accumulator 23 and a device 7A for detecting any gas bubbles intended to control an expansion valve 17A.

Then the expansion valve. 17A opens streams of condensed refrigerant to the low pressure side 19 of the system where the medium expands.

Thereafter, the medium flows on to an evaporator 20 where heat absorption to refrigerants takes place from gas, usually air, or liquid, whereby the refrigerant liquid evaporates. The gas / liquid mixture is then pressed to a liquid separator 24 where liquid is separated from gas. A part of the liquid is forced to pass by means of gravity a heat exchanger where oil and refrigerant liquid are separated, after which oil is returned to the compressor 2 via the accumulator 23 and a suction line 1. Return of liquid which has not evaporation takes place from the liquid separator 24 via pipe 25 to the evaporator 20. The compressor 2 compresses the refrigerant which is then cooled in the condenser 4 where the condensation takes place.

Figure 2 shows a device 7A according to a preferred embodiment which is provided with a drying filter 22 and sight glass 25.

As not all gas is condensed at the passage through the condenser 4, there may still be gas bubbles left in the refrigerant. The device 7A separates the gas which has not condensed directly inside the sight glass 25 so that the control process with separation of gas bubbles can be observed. During compressor operation, gas flows via signal tube orifice 14 through a choke 8 into a signal tube 6. The gas then passes a heat exchanger device 11 after which the signal tube 6 transforms into a signal tube 10. Optionally, an electric heater can also be connected to the signal tube 10. The gas provides causes a pressure change affecting an expansion valve diaphragm 12A diaphragm 12 connected to the signal tube 10. The pressure changes affecting the diaphragm 12 in turn actuate a mechanism 13, such as a piston, by which the opening of the expansion valve is controlled. A choke 18, which on its outlet side is connected to the low pressure side 37 of the cooling system, is also arranged in connection with said pipe 10. Depending on the gas pressure which the gas flow causes, the gas flows out through the choke 18. This gives the space before the membrane 12 a pressurization which is higher than the reference pressure in the space after the diaphragm 12 connected to the low pressure side 37 via a compensating line 26.

When liquid, i.e. condensate, enters the inlet to the signal line 14, it must pass the choke 8, whereby an expansion takes place and the liquid evaporates due to the pressure drop which the choke 8 entails. The liquid gas mixture formed in signal line 6 after the choke 8 is then further evaporated in one of the heat exchanger devices 11, 34. During the evaporation, a volume increase takes place and essentially all the liquid changes to gaseous form. The gas is then passed further in the line 10 to a pressure sensing expansion valve 17A which by means of a mechanism 13 is actuated to be opened 16 whereupon the gas is forced via the choke 18 to the low pressure side 37 of the cooling / heat pump system.

When gas or gas-mixed liquid instead of pure liquid enters the inlet to the signal line 14, a smaller increase in volume occurs than if pure liquid enters as above. Thus, the pressure in the signal line 10 is affected, which also affects the valve mechanism 13 to close. If the mechanism 13 closes, the flow through the valve 17A of the condensate flowing through the condensate line 9 coming from the device 7A is restricted. The choke 8 has a smaller flow-through capacity than the choke 18, which means that even a small amount of uncondensed refrigerant is able to give the expansion valve 17A an opening pulse.

A line 36A is provided in parallel with the expansion valve 17A. When the valve is closed, a signal flow will be obtained through the valve so that a faster impulse can take place to the intake 14 of the signal line 6 after the cooling system is started up.

Figure 3 shows a heat exchanger device 11 for evaporating liquid flowing through the signal tube 6, 10. The tube 6, 10 preferably has an outer diameter of about 3 millimeters and is attached in a loop to a tube 3, 9, containing hot gas and condensed, in order to achieve as large a heat exchange as possible.

Figure 4 shows a control system according to an alternative embodiment according to the present invention. Instead of the device 7A used for detecting any gas bubbles according to the embodiment shown in Figure 1, a float device 7B is used in this embodiment. The float device 7B transmits control pulses to a thermostatic expansion valve 17B via a signal line 31, a temperature sensing sensor body 28 and a signal line 27.

With sufficient supply of condensate from the condenser 4, a float 29 is raised and a valve 30 is opened, liquid flowing into a signal line 31. A choke 18 located between the intake valve 30 of the signal line 31 and the low pressure side 37 of the system is adapted for the valve 30 flow capacity in relation to the choke 18, in such a way that a temperature increase takes place in the signal line 31 and in the sensing body 28 when the flow of refrigerant through valve 30 is sufficiently large. The throttle 18 is adapted for a smaller flow than the intake valve 30 when this valve is fully open.

When the refrigerant flow through the signal line 31 exceeds a certain level, the choke 18 is not able to let through a sufficient amount of refrigerant for a sufficient evaporation of the refrigerant from liquid phase to gas phase to take place in the signal line 31, so the temperature in this line 31 increases. opens.

When the intake valve 30 is not required to be open and thus does not provide sufficient liquid supply to the signal line 31, an evaporation takes place in the signal line 31 which is sufficient to lower the temperature in said line 31. The sensor body 28 for the thermostatic expansion valve 17B registers the temperature reduction reduced vapor pressure in the space above the bellows diaphragm 12. This pressure reduction causes the diaphragm 12 to command the mechanism 13B of the expansion valve 17B to close, thereby reducing the flow through the expansion valve 17B. 10 15 20 25 30 Cm ß fl, _ Öuvnf P 1 .: ___, ï "\ The system according to Figure 4 can also be provided with a heater or the like to evaporate liquid present in the signal line 31, even if it is not required.

The system according to the invention provides a cooling / heating system that is simple and inexpensive and provides fast control.

The invention means that a small amount of condensate from the valve 30 can control a much larger amount of condensate via the expansion valve 17B.

Of course, the invention is not limited to the embodiments described above and illustrated in the accompanying drawings. Modifications are possible, especially with regard to the nature of the various parts, or by using comparable techniques, without departing from the scope of protection specified in the patent claims.

Reference designations Suction line gas without liquid mixture Compressor Condenser for removal of heat. Air or liquid affected l 2 3 Hot gas line 4 5 Condensate line Signal line after throttling 8 before heating ll 7A Device for checking the presence of gas bubbles. 7B Float and float housing with valve. 8 Throttle 9 Condensate line 10 Signal line 11 Heat exchanger 12 Pressure diaphragm 13 Piston affected by diaphragm and controls the expansion valve 17 14 Inlet to signal line 6,10 10 15 20 25 l5 l6 17 17 18 19 20 21 of 22 23 24 25 26 27 28 29 30 31 32 33 34 35 Closing function Opening function A Expansion valve B Thermostatic Expansion valve Throttle Expansion line, low pressure side Evaporator for absorbing heat Oil return from liquid separator with heat for evaporation refrigerant Drying filter Accumulator Liquid separator Separation signal Sewing glass

Thermobulb / sensing body Float body Valve affected by float 29 Signal line between float valve and throttle 18 Valve closes at low liquid level Valve opens at high liquid level Electric heating Heat exchanger for liquid subcooling / heat recovery from condensate valve 36A L signal

Claims (16)

10 15 20 25 30 Sfnra fïzgg (f. (_) I n) “T 10 PATENTKRAV Cooling or heating device comprising at least one compressor (2), a condenser (4), an expansion device (17A; 17B) and an evaporator (20), characterized in that in connection with an outlet of the condenser (4) is a control device (7A; 7B) arranged to receive liquid from the condenser (4) and which comprises an outlet to a condensate line (9) and an inlet (14; 30) to a signal line (6, 10; 31), that the condensate line (9) communicates with the expansion device (17A; 17B) that means (8, 11, 34) are provided for evaporating liquid taken in the signal line (6, 10; 31), the amount of liquid being evaporated in the signal line ( 6, 10; 31) influences the pressure in the signal line (6, 10; 31) that means (12, 13) are connected to the signal line (6, 10; 31) for regulating the opening process of the expansion device (17A; 17B), said regulation is affected by the pressure in the signal line (6, 10; 31). Cooling or heating device according to claim 1, characterized in that a throttle (8) is arranged in connection with the inlet (14) of the signal line (6) in order to effect a pressure drop and thereby evaporate liquid present. Cooling or heating device according to one of the preceding claims, characterized in that said signal line (6, 10; 31) is connected to a heat supply device (11, 34) for evaporating liquid present in the signal line. 10 15 20 25 30 ll Cooling or heating device according to any one of the preceding claims, characterized in that said signal line (6, 10; 31) is attached in a loop to pipes (3), containing hot gas, and / or to pipes (9), containing condensate, for evaporation of liquid flowing through the signal line (6, 10; 31) - Cooling or heating device according to one of the preceding claims, characterized in that the outlet to the condensate line (9) is located at the bottom of the control device (7A) and that the inlet (14) of the signal line (6) from said control device (7A) is located so that gas bubbles present in the condensate are led into the inlet (14) and separated from the condensate which is led into the condensate line (9). Cooling or heating device according to one of the preceding claims, characterized in that the control device (7A) is provided with a sight glass (25) in order to enable the separation of gas bubbles to be observed. Cooling or heating device according to one of the preceding claims, characterized in that a line (36A) is arranged parallel to the expansion device (17A). Cooling or heating device comprising at least one compressor (2), a condenser (4), an expansion device (17A; 17B) and an evaporator (20), characterized in that in connection an outlet of the condenser. (4), a control device (7A; 7B) is arranged to receive liquid from the condenser and which comprises an outlet to a condensate line (9) and an inlet (14:30) to a signal line (6, 10; 31), 15 20 25 30 CN ß fi CG “J \ .. J \ .on 12 that the condensate line (9) is connected to the expansion device (17A; 17B), that the amount of liquid evaporated in the signal line (6, 10; 31) affects the temperature in the signal line (6, 10; 31), that means (12, 13) are connected to the signal line (6, 10; 31) for regulating the course of the expansion device (17A; 173), said control being influenced by the temperature in the signal line. the wire (6, 10; 31). Cooling or heating device according to claim 8, characterized in that a float (29) is arranged to control the input (30) of the signal line (31) from said control device (7B). Cooling or heating device according to one of the preceding claims, characterized in that a sensing body (28) is arranged in or adjacent to the signal line (31) for measuring the temperature in the signal line (31). Cooling or heating device according to one of the preceding claims, characterized in that a choke (18) is arranged between the signal line (6, 10; 31) and the low-pressure side (37) of the system. Cooling or heating device according to one of the preceding claims, characterized in that the opening process of the expansion device (17A; 17B) is controlled by a piston (13) which is actuated by a pressure diaphragm (12). 10 l5 20 25 30 5 7: Å "i 13 A method of controlling a cooling or heating device comprising at least one compressor (2), a condenser (4), an expansion device (17A; 17B) and an evaporator (20), characterized in that it comprises the steps of: - conducting liquid from a control device (7A) to a condensate line (9) and to an inlet (14; 30) to a signal line (6, 10; 31), - evaporating the liquid which is led into the signal line (6, 10; 31 ), - control the opening process of the expansion device (17A; 17B) connected to the condensate line (9) due to pressure changes in the signal line (6, 10; 31) caused by said evaporation. Method for controlling a cooling or heating device according to claim 13, characterized in that the liquid present in the signal line (6, 10) is evaporated by supplying heat or by lowering the pressure in the signal line (6, 10). . Method for controlling a cooling or heating device according to one of Claims 13 to 14, characterized in that substantially gas bubbles are led into the inlet (14) and are thus separated from the condensate which is led into the condensate line (9). which is preferably located at the bottom of the control device (7A). A method of controlling a refrigeration or heating device comprising at least one compressor (2), a condenser <4 »(20), characterized in that it comprises the steps of: an expansion device (17B) and an evaporator sensor. LD w -J l 14 lead liquid from a control device (7B) to a condensate line (9), regulate the liquid supply to an inlet (30) to a signal line (31), control the opening process of the expansion device (17B) connected to the condensate line (9) due to temperature changes in the signal line (31) caused by the evaporation of the liquid.