NO144303B - HEAT PUMP DEFINITION DEVICE. - Google Patents

Description

This invention relates to a defrosting device for a heat pump. Defrosting devices for various purposes are previously known in several designs. It can e.g. reference is made to US patents 3,013,399, 3,726,104, 3,643,457 and others. The device according to the invention is of the type that comprises an air duct, a heat exchanger which is flow-wise connected to a compressor and formed by a number of coolant lines arranged inside an air duct, heating devices for periodic defrosting of the heat exchanger device and devices for starting a defrosting cycle by the influence of the heating devices when a predetermined amount of frost has built up on the heat exchanger.

A heat pump system usually comprises a compressor unit and a heat exchange system with an evaporator for a relatively low temperature and a condenser for a relatively high temperature. Often the compressor and evaporator are combined into one unit and the compressor is usually arranged within the cooling coils of the evaporator so that air cooled by the evaporator can be used to cool the compressor. Investigations have recently shown that, for various reasons, such a device is not very advantageous when it comes to the utilization of energy. It has therefore been proposed to separate the compressor from the evaporator and install the first indoors and the second outdoors to reduce heat loss in cold weather.

When the heat pump is in operation, frost or ice often forms on the evaporator's heat exchange coils. The amount of frost that forms is a function of the ambient temperature and the relative humidity, and greatest frost formation takes place at temperatures around 0°C and in a saturated atmosphere. As frost build-up prevents air flow past the heat exchanger, the unit must be defrosted at intervals. Previously, the defrosting operation was started at predetermined time intervals. These time intervals then had to be chosen so that sufficient defrosting was carried out when frost formation was maximum. Under other temperatures and humidity conditions when frost formation was less, the defrosting system therefore works too often. This meant a significant loss of energy.

Attempts have also previously been made to initiate defrosting operations by sensing the change in pressure loss above the heat exchanger. When frost builds up, the pressure on the heat exchanger's downstream side decreases. This reduction is sensed with a barometric pressure differential switch. The difficulty with such a device is that the switch must close switch contacts reliably at pressure changes of the order of magnitude as small as 1/20 cm V.S. Until now, it has been difficult or impossible to manufacture such sensitive pressure switches, at least on an economically acceptable basis.

Besides difficulties in determining the beginning

(and the end) of defrosting cycles, the previously known heat pump systems were less satisfactory when it came to performing the defrosting itself. Usually, the previously known heat exchangers are constructed so that air flows through them along a substantially horizontal path. If the pre-heated air is not heated evenly and well mixed, significant temperature differences occur between the upper and lower parts of the horizontal path, which leads to different defrosting times, local overheating etc. Therefore, defrosting systems are usually used which heat the rimmed winding from the inside by reversing the cooling cycle. Such operation with a hot evaporator and cold condenser produces sudden pressure reductions in the low pressure side of the system, causing little refrigerant flow and a high probability of inefficient cooling and lubrication of the hermetically sealed motor compressor unit and therefore an increased frequency of motor failure.

The purpose of the invention is to provide a device for defrosting heat exchangers in heat pumps that is more efficient and reliable than the previously known devices for the same purpose. The device according to the invention is distinguished essentially by the fact that it includes a device for producing an auxiliary air flow at a place downstream of the heat exchanger from a place outside the air duct to a place in the duct, devices for sensing changes in the auxiliary flow caused by the formation of frost on the heat exchanger device, and devices for starting the heating device as a result of sensing a predetermined change in the auxiliary air flow .

In an advantageous embodiment of the invention, a heating device with constant heat output is arranged in the auxiliary flow and the device comprises temperature sensors for determining temperature changes in the auxiliary flow which. as a result of variations in the air volume of the auxiliary flow as a result of frost formation on the heat exchanger. In addition to temperature sensors for sensing the temperature in the auxiliary air flow, the device can include another temperature sensor for sensing an essentially constant reference temperature, e.g. the temperature of the ambient air outside the air duct. When a predetermined temperature drop in the auxiliary air flow has been sensed, a switch is closed which then energizes the heating device for defrosting and stops the compressor, the suction fan and switches off the heater with constant heat output which is arranged in the auxiliary flow. The defrost cycle continues during measurement e.g. of the temperature of the air flow through the heat exchanger or of the temperature of the heat exchanger itself. The defrost cycle ends when the aforementioned switch is reopened when a predetermined temperature or temperature difference is reached.

The auxiliary air flow device may comprise a line with a relatively small cross-section. A control device may be provided which initiates the defrosting cycle when the temperature in the auxiliary air flow device has fallen to a predetermined value as a result of a reduction in the air flow past the heat exchanger having led to the activation of a device that increases the air flow and thus the temperature drop in the auxiliary air flow device. The control device for starting the heating device can start working, e.g. when the temperature increase in the auxiliary air flow has been reduced by approximately 50% in relation to the temperature increase when the heat exchanger is essentially frost-free.

The device according to the invention eliminates the use of the hitherto usual defrosting system with a fixed time interval for defrosting, which is energy-wasting. It also eliminates the unreliable and sometimes dangerous low pressure differential switches. Instead, in accordance with the invention, the pressure loss across the heat exchanger is sensed indirectly, but in a simple, cheap, relatively sensitive and completely reliable way. This ensures a better function for the heat pump and less total energy consumption.

The invention will be explained in more detail below by means of an example with reference to the drawing which schematically shows a heat pump made in accordance with the invention and more specifically the construction and placement of the heat exchanger in a surrounding air duct as well as the structure of the defrosting initiator.

The figure shows a heat pump 2 which comprises a compressor unit 4 mounted separately and at a distance from an evaporator heat exchanger 10 and a defrosting device 6 for this. Other conventional heat pump components, such as a condenser or an expansion valve, are also provided. However, for the sake of simplicity, they are neither shown separately nor described. The defrosting device generally comprises an upright air duct 8 which surrounds the heat exchanger or evaporator 10 and which has an air intake 12 above a foundation frame 14 and an air outlet 16 on the top 18 of the duct. Normally, the heat exchanger has a rectangular ground plan, which in this case is square, and the air duct has a complementary cross-section.

A suction fan 20 driven from a motor 22 is arranged axially in the duct near its top and is supported by a suitable support structure 24 which in turn is supported by the duct's upright side walls 26. During normal operation the fan sucks air through the duct's air intake 12 and the air rises vertically up past the heat exchanger 10 and then leaves the channel.

As already mentioned, frost often forms on the heat exchanger. The amount of frost formed is a function of ambient temperature and humidity and is greatest when the temperature is near 0°C and the atmosphere is saturated with humidity. When frost forms on the heat exchanger, it prevents the passage of air and heat transfer between the air and the heat exchanger. Therefore, the heat exchanger must be defrosted at intervals.

The heat exchanger 10 comprises several horizontally arranged heat exchange coils or wires 28 which are arranged in several, e.g. three, parallel winding layers 30. A larger number of separate, parallel heat exchange fins or ribs are thermally connected to the outside of each winding 28, e.g. by soldering, and positioned so that air can flow vertically past the fins and windings, as indicated by vertical arrows in the drawing. The fins are only indicated schematically in the drawing by a generally rectangular box whose outline corresponds to the outline of the entire fin array attached to all windings. The individuals

fins have rectangular, e.g. square, shape.

The winding layers 30 are arranged horizontally or somewhat at an angle and form an angle with the horizontal that is not greater than approximately 10°. It is preferable that the edges 33 of the fins are parallel to the winding layer 30, as such an inclination of the edges facilitates the removal of water which forms during the defrosting cycle.

Below, i.e. on the upstream side of the heat exchanger 10, there is an electric resistance heater 34 constructed as described above and fixed in the usual way to the side wall 26 of the channel. During a defrosting period, the resistance heater is energized so that the heated air rises as a result of convection upwards in the space between the heat exchange fins 32 for melting the rime that has formed on the windings and the fins or ribs. In those cases where the winding layers lie at an angle (as shown in the drawing), guide plates 36 are arranged to control the air flow to ensure an even supply of air to all parts of the heat exchanger. The baffle device comprises several parallel, upright walls 38, which divide the convection air flow into vertical columns. Thereby, a more efficient heat exchanger with a uniform defrosting effect has been achieved.

For control, i.e. to the start and end of. the defrosting cycles, according to the invention, a defrosting starter 40 is arranged which generally comprises a pipe 42 with a relatively small diameter, e.g. 19 mm, for guiding an auxiliary air flow. The pipe extends through the side walls 26 of the channel and has an intake 44 on the outside of the channel and an outlet 46 on the inside of the channel at the downstream part of the channel between the heat exchanger 10 and the fan 20.

A pack of current-inhibiting material, such as stainless steel wool 48 or a blind etc. is placed in the pipe for controlling air flow through the same. The density and thickness of the steel wool packing can e.g. be set so that during normal operation an auxiliary airflow with a flow rate of 28 dm^/min. will be formed, i.e. with the fan 20 running and little or no frost on the windings 28 and the cooling fins 32.

A heater 50 with constant performance is in connection with an energy source 52 and is arranged in the pipe 42 for heating the auxiliary air flow. It will be understood that as long as the air volume per time unit remains constant, the heater will contribute to increasing the temperature of the auxiliary air stream by a constant value. However, when the volume of air through the pipe changes, the temperature of the heated air will increase or decrease depending on whether the flow-through volume becomes smaller or larger. In the example here, where the pipe packing is set so that the normal flow through is 28 dm 3/min., the arrangement of a heating element with a constant output of 10 watts will lead to a temperature increase in the flowing air of approximately 13, 9°C.

A first temperature sensor 54 is arranged in the pipe 4 2 on the downstream side of the heater 50 and is operatively connected to a control 56 which comprises a main switch. The switch is preferably a temperature difference switch with electrical or mechanical design and is connected to another temperature sensor 58 which is arranged outside the duct for measuring the temperature in the surrounding air. Alternatively, the second temperature sensor can be arranged in the channel, but on the upstream side of the pipe 42 for measuring the temperature of the air flowing through the channel. For practical reasons, the temperature of this air varies with the temperature variation of the surrounding air.

The switch 56 in turn controls a defrost relay 60, so that the resistance heater 34 is connected to the energy source 62 for starting the defrost cycle. The switch 56 simultaneously operates a main control relay 63 for switching off the heat pump during the defrost cycle, i.e. for switching off the compressor 4 and the fan 22. The switch 56 also de-energizes the heater 50 when the defrost is in progress.

When the heat pump is in operation and the heat exchanger 10 is completely or essentially defrosted, approximately 28 dm<3> of air is drawn per my. through pipe 42. This air is heated approximately 13.9° above the ambient temperature. The switch 56 is set so that the resistance heater 34 is de-energized and the fan motor 22 works with this auxiliary air temperature. When frost builds up on or between the coils 28 and the fins 32, the pressure loss across the heat exchanger increases. The consequence is that the pressure in the downstream part of the channel 8 between the heat exchanger and the fan 20 decreases slightly, which in turn leads to an increase in the flow volume (per time unit) of air

which flows through pipe 42.

The increased amount of air flowing through the pipe causes a corresponding reduction in the temperature rise. The switch 56 is set so that it is in operation when there is a predetermined temperature reduction of the heated, flowing air.

Claims (7)

1. Defrosting device for a heat pump comprising an air duct, a heat exchanger (10) which is flow-wise connected to a compressor (4) and formed by a number of coolant lines (28) arranged inside an air duct (8), heating devices (34) for periodic defrosting of the heat exchanger device and devices (40) to initiate a defrosting cycle by the influence of the heating devices when a predetermined amount of frost has built up on the heat exchanger, characterized in that the defrosting device comprises a device (42) for producing an auxiliary air flow at a location downstream of the heat exchanger ( 10) from a place outside the air duct (8) to a place in the duct, devices (54,58) for sensing changes in the auxiliary flow caused by the formation of frost on the heat exchanger device, and devices (56,60) for starting the heating device ( 34) as a result of sensing a predetermined change in the auxiliary air flow. 2. Device according to claim 1, characterized in that a heating device (50) with constant heat output is arranged in the auxiliary flow and that the device includes temperature sensors (54) for determining temperature changes in the auxiliary flow as a result of variations in the air volume of the auxiliary flow as a result of frost formation on the heat exchanger ( 10). 3. Device according to claim 2, characterized in that, in addition to a first temperature sensor (54) for the temperature in the auxiliary air flow, it has another temperature sensor (58) for sensing an essentially constant reference temperature. 4. Device according to claim 3, characterized in that the second temperature sensor (58) senses the temperature in the surrounding air outside the air duct (8). 5. Device according to claim 3, characterized in that the second temperature sensor (58) is arranged for sensing the air temperature that flows past the heat exchanger device. 6. Device according to one of claims 1-5, characterized in that the auxiliary air flow device comprises a line (42) with a relatively small cross-section with an inlet end (44) outside and an outlet end (46) in the air duct (8). 7. Device according to one of claims 2-6, characterized in that a control device (56) initiates the defrost cycle when the temperature in the auxiliary air flow device (42) has fallen to a predetermined value as a result of a reduction of the air flow past the heat exchanger (10) to start a device (20) which increases the air flow and thus the temperature drop in the auxiliary air flow device. 8.. Device according to claim 6, characterized in that the device (56) for starting the heating device (34) begins to work when the temperature increase in the auxiliary air flow has been reduced by approximately 50% in relation to the temperature increase when the heat exchanger (10) is essentially frost-free .