Technical field

The present invention concerns a cooling or heating apparatus including at least a compressor, a condenser, an expansion apparatus and a vaporiser.

The invention also concerns a method for controlling a cooling or heating apparatus including at least a compressor, a condenser, an expansion apparatus and a vaporiser.

The invention will be applied to cooling and heating systems with vaporising/condensing coolants as the working medium. The system according to the invention can be applied to all types of cooling system such as air-conditioning, heat pumps, process and apparatus cooling systems that use a piston compressor, screw compressor, scroll compressor, centrifugal compressor, rotation compressor or some other type of compressor and all types of coolants for heat exchange via vaporization/condensation.

State of the art

On the market there are different system for regulating and controlling cooling and heating. However, the systems that are used are often complicated and require a large volume and are thereby needlessly expensive. The size and complexity of the systems also means that the control speed and effectiveness is lower than expected. Some previously known systems that have some of the above mentioned disadvantages will be described briefly below.

US-A-4,566,288 and GB-A-659,051 concern different float systems that either affect a valve directly or affect a valve indirectly via electric impulses and send signals to a valve for condensate outflow. These systems are both complicated and

controlled with the help of electric impulses and are thereby not self-actuating, and they are large and voluminous with a valve connected to a float for controlling the whole amount of condensate.

US-A-3,388,558 and EP-A-0, 939, 880 concern systems with thermostat valves that with the help of electrical heating of the system's thermal part affect a membrane that on pressure increase opens a valve. Neither are these system self-actuating since the control impulse consists of electric resistances for heating a bulb with an external modulation control signal for heating.

US-A-5, 156, 017 shows a temperature controlled system that controls the flow with the help of the temperature difference between the exit condensate's supercooling and the condensation temperature. However, these controls do not make full utilization of the condenser surfaces possible since a supercooling loop is required in order to control the exit condensate.

US-A-3, 367, 130 concerns a system with a traditional thermostatic expansion valve that controls the difference between the vaporisation temperature and overheated gas after the vaporiser with the help of impulses from a gas filled thermosensitive sensor. The system is controlled via overheating gas after vaporization which means that the control impulse for the expansion valve can affect the temperature difference between the coolant and the heat emitting medium negatively.

US-A-4, 267, 702 concerns systems with a pressure sensitive valve that entirely or partly turn the liquid supply off depending on the pressure difference between operation and stop. However, the systems do not control condensate outflow depending on uncondensed gas. The control function is thus not affected by condensate quality.

There is thus a need of a system that in a simple, smooth and easy way solves the problems with the above mentioned systems .

Description of the invention

A purpose of the present invention is to solve the problem that gas in the condensate causes unnecessary power losses.

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

According to a specific embodiment a purpose of the invention is to solve the problem of recycling supercooling heat without decreasing the condenser's condensing power.

According to a first preferred embodiment a purpose of the invention is to solve the problem of controlling the liquid flow with the help of pressure impulses to already known valve constructions .

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

A specific purpose of the invention is to control liquid flow in such a way that the system is self-actuating without needing external, for instance electric, control apparatus.

Finally, a purpose of the invention is to solve the problem of providing a vaporiser surface with coolant without needing to overheat suction gas for controlling the flow.

Said purposes are achieved with a cooling and heating apparatus as given in the characterising portions of patent claims 1 and 14 and the dependent claims belonging to them.

Brief description of the figures

The invention will be described in the following in a non- limiting way and for illustrative reasons with reference to the attached figures in which:

Figure 1 shows a control system according to a preferred embodiment according to the present invention,

Figure 2 shows a device for detection of gas bubbles according to the present invention,

Figure 3 shows a heat exchanger according to the present invention,

Figure 4 shows a control system according to an alternative embodiment according to the present invention, and

Figure 5 shows a float apparatus according to the present invention.

Figure 6 shows an alternative placement of a control apparatus .

Detailed description of the invention

Figure 1 shows a system for thermal, cooling, or freezing systems. The system consists of channels containing coolant (not shown), a compressor 2, a condenser 4, an expansion valve 17 A, a vaporiser 20, a liquid separator 24, an oil return apparatus 21, an accumulator 23 and a device 7A for detection of the presence of gas bubbles intended to control an expansion valve 17A.

When the expansion valve 17A opens condensed coolant flows to the system's low pressure side 19 where the medium expands. Thereafter the medium flows further to a vaporiser 20 where heat uptake to coolants takes place from gas, usually air, or liquid, whereby the coolant liquid vaporises. The gas/liquid mixture is then pressured to a liquid separator 24 where liquid is separated from gas. With the help of gravitation some of the liquid is made to pass through a heat exchanger where oil and coolant liquid are separated, after which oil is returned to the compressor 2 via the accumulator 23 and a suction line 1. Return of liquid that has not been vaporised takes place from the liquid separator 24 via channel to the vaporiser 20. The

compressor 2 compresses the coolant that is thereafter cooled in the condenser 4 where condensation takes place. In figure 6 an alternative embodiment form is shown where the control apparatus 7A is placed in the condenser in front of its outlet. In figure 2 a device 7A is shown according to a preferred embodiment that is provided with a drying filter 22 and inspection glass 25. As not all the gas condenses on passage through the condenser 4 there can still be gas bubbles left in the coolant. The device 7A separates the gas that has not condensed directly inside the inspection glass 25 so that the control process with separation of gas bubbles can be seen. During compressor operation gas flows via the signal channel opening 14 through an orifice 8 into a signal channel 6. The gas then passes a heat exchanger 11 after which the signal channel 6 changes into in a signal channel 10. An electrical heater can possibly be coupled to the signal channel 10. The gas gives rise to a pressure change that affects an expansion valve 17A membrane 12 attached to the signal channel 10. Pressure changes that affect the membrane 12 in turn affect a mechanism 13, for instance a piston, whereby the expansion valve opening is controlled. An orifice 18 that on its output side is connected to the cooling system's low pressure side 37 is also arranged in proximity to said channel 10. Depending on the gas pressure that the gas flowthrough produces gas flows out through the orifice 18. This gives the space in front of the membrane 12 a pressurisation that is higher than the reference pressure in the space behind the membrane 12 attached to the low pressure side 37 via a compensation channel 26.

When liquid, that is to say condensate, enters the inlet to the signal channel 14 it must pass the orifice 8, whereby an expansion occurs and the fluid vaporises because of the pressure reduction that the orifice 8 entails. The liquid gas mixture that is formed in the signal channel 6 after the

orifice 8 then vaporises additionally in one of the heat exchanger apparatuses 11, 34. During vaporisation a volume increase occurs and essentially all the liquid changes into gas form. Thereafter the gas is led further in the channel 10 to a pressure sensitive expansion valve 17A that with the help of a mechanism 13 is made to open 16 whereupon the gas is pressured via the orifice 18 to the cooling/heat pump system's low pressure side 37.

When gas or gas mixed liquid instead of pure liquid enters the inlet to the signal channel 14 a smaller volume increase occurs than when pure liquid enters according to the above. The pressure in the signal channel 10 is affected thereby which also makes the valve's mechanism 13 close. If the mechanism 13 closes the flow through the valve 17A is shut off for the condensate that flows through the condensate channel 9 that comes from the device 7A. The orifice 8 has a smaller flowthrough capacity than the orifice 18 which means that even a small amount of uncondensed coolant can give the expansion valve 17A an open impulse.

The orifice 18 maintains a higher pressure from the high pressure side relative to the low pressure side in order to make a signal to the expansion valve possible.

A channel 36A is arranged parallel to the expansion valve 17A. When the valve is closed a signal flow is obtained through the valve so that a faster impulse can occur to the signal channel's 6 intake 14 after the cooling system is started up.

In figure 3 a heat exchanger 11 for vaporization of liquid that flows through the signal channel 6, 10 is shown. The channel 6, 10 preferably has an outside diameter of about 3 millimetres and is attached to a channel 3, 9, preferably in a loop, containing hot gas or condensate, respectively, in order to achieve as large a heat exchange as possible.

In figure 4 a control system according to an alternative embodiment according to the present invention is shown. Instead of device 7A that is used for detection of the presence of gas bubbles according to the embodiment shown in figure 1, a float apparatus 7B shown in figure 5 is used in this embodiment. Via a signal channel 31, a temperature sensitive sensor 28 and a signal channel 27 the float apparatus 7B gives control impulses to a thermostatic expansion valve 17B.

For sufficient supply of condensate from the condenser 4 a float 29 is raised 33 and a valve 30 is opened, whereby liquid flows into a signal channel 31. An orifice 18 situated between the signal channel's 31 inlet valve 30 and the system low pressure side 37 is adjusted to the valve's 30 flow capacity relative to the orifice 18 in such a way that a temperature increase occurs in the signal channel 31 and in the sensitive element 28 when the flow of coolant through the valve 30 is strong enough. The orifice 18 is adjusted for a smaller flowthrough than the inlet valve 30 as this valve is fully open. Here the orifice 18 maintains a higher temperature on the high pressure side relative to the low pressure side's temperature .

When the coolant flow through the signal channel 31 exceeds a certain level the orifice 18 cannot pass a sufficient quantity of coolant to allow sufficient vaporization of coolant from the liquid phase to the gas phase to take place in the signal channel 31 for which reason the temperature in this channel 31 increases which leads to the expansion valve' s 17B being opened.

When the inlet valve 30 is not required to be open and thereby does not provide a sufficient liquid supply to the signal channel 31 vaporization occurs in the signal channel 31 that is enough to lower the temperature in said channel 31. The sensitive element 28 for the thermostatic expansion valve 17B

registers the temperature reduction which entails a reduction in steam pressure in the space over the bellows membrane 12. This pressure reduction leads to the membrane 12 giving the expansion valve 17B mechanism 13 an order to close, whereby the flow through the expansion valve 17B decreases.

The system according to figure 4 can also by supplied with a heater or the like in order to vaporize liquid present in the signal channel 31 even if that 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 results in a small quantity of condensate from the valve 30 being able to control a much larger quantity of condensate via the expansion valve 17B.

Of course the invention is not limited to the embodiments described above and illustrated in the attached drawings. Modifications are feasible, especially concerning the different parts' nature, or through using comparable techniques, without departing from the protected area given in the patent claims because of them.

Reference symbols

1 Suction line gas without liquid admixture.

2 Compressor

3 Hot gas channel

4 Condenser for removal of heat. In contact with air or liquid.

5 Condensate channel

6 Signal channel after orifice 8 before heating 11. 7A Device for control of the presence of gas bubbles. 7B Float and float housing with valve.

8 Orifice

9 Condensate channel

10 Signal channel

11 Heat exchanger

12 Pressure membrane

13 Piston affected by a membrane and controlling the expansion valve 17.

14 Intake to signal channel 6, 10

15 Closing function

16 Open function 17A Expansion valve

17B Thermostatic expansion valve

18 Orifice

19 Expansion channel, low pressure side.

20 Vaporiser for heat uptake.

21 Oil return from liquid separator with heat for vaporization of coolant.

22 Drying filter

23 Accumulator

24 Liquid separator

25 Inspection glass

26 Signal channel, compensation channel.

27 Signal channel to expansion valve.

28 Thermal bulb/sensor

29 Float body

30 Valve affected by the float 29.

31 Signal channel between the float valve and the orifice 18.

32 Valve closes at low liquid level.

33 Valve opens at high liquid level.

34 Electric heating

35 Heat exchanger for liquid supercooling/heat recovery from condensate .

36A Signal flow past expansion valve . 37 Low pressure side