NO172151B - PROCEDURE AND DEVICE FOR OPERATING MONITORING OF A ROTATING HEAT EXCHANGER - Google Patents

Description

Method and device for operational monitoring of a rotary heat exchanger.

The present invention relates to a method and a device for operationally monitoring a rotatable heat exchanger of the type that appears in the introduction to patent claim 1.

A known method for monitoring a rotating heat exchanger involves continuously checking whether the rotor is really rotating by means of magnetic or inductive sensing. Thus, an alarm signal is obtained if the rotor has stopped, which may for example be due to a drive belt for the rotor having broken. This monitoring method is relatively expensive and also has the disadvantage that other operating disturbances, such as clogging of a filter or accidental mixing of outside air into the outflow air, cannot be detected.

Against this background, the purpose of the present invention is to produce reliable operational monitoring of a rotary heat exchanger of the kind indicated at the outset in a simpler and cheaper way, so that operational disturbances other than a stationary rotor should also be indicated.

This purpose is achieved according to the invention by the special features indicated in the characterizing paragraphs of patent claims 1 and 3, as operational monitoring then takes place by measuring the temperature of the inflow air and an alarm is indicated if the air temperature is lower than a predetermined temperature value, for example +10 °C, and which is lower than the temperature that can be expected after normal heat recovery in the heat exchanger rotor.

This method, or device, is extremely simple and inexpensive due to the fact that only a single temperature sensor is needed for operational monitoring, and no complicated signal processing is required for alarm indication. Operational monitoring by temperature sensing is in and of itself previously known from SE-B-442 055, but here three different temperature sensors are used for measuring the temperature of the outdoor air, the inflow air and the outflow air, respectively, as well as calculating the efficiency of the heat exchanger expressed as the ratio between, on the one hand, the difference between the temperature of the inflow air and the outside air and, on the other hand, the difference between the temperature of the outflow air and the outside air. The determination of this efficiency will necessarily be rather cumbersome and expensive.

However, it has surprisingly turned out that the extremely simple method and device according to the invention provides an equally safe and reliable monitoring of the normal working function of a rotary heat exchanger.

Operational disruption instructions are thus obtained in the following cases:

- stationary rotor,

- accidental mixing of outdoor air into the exhaust air, and

- insufficient flow of exhaust air.

Several different operating disturbances can therefore be sensed.

The fact that some operating disturbance indication cannot be achieved at high outside air temperatures, for example above +10°C, does not pose a problem, as heat exchangers of this type are normally shut down (by the rotor no longer rotating) under such conditions,

for example in the summer.

Rotary heat exchangers often have a reheater which usually consists of electrical resistance elements or a water-borne heating coil. In order to create the desired operational monitoring in such cases, the temperature sensor for the inflow air should be placed between the rotor and the afterheater (see patent claims 2 and 5), and then suitably shielded from the afterheater's heat radiation (compare patent claims 6 and 7). Furthermore, it has proven to be particularly advantageous to place the air temperature sensor on the side of the channel's midpoint, as specified in patent claim 4. Thereby, a good margin is achieved for erroneous alarm triggering at certain occurring outside air temperatures.

The invention will now be more clearly illustrated with the help of a simple design example and with reference to the attached drawing, on which: Figure 1 schematically shows a rotating heat exchanger with temperature sensor for operational monitoring in accordance with the present invention, and Figure 2 schematically shows the heat exchanger rotor seen from the right in

Figure 1.

The heat exchanger shown in Figure 1 comprises two mutually adjacent channels 1^2, where outflow air (F) flows into the upper channel 1 inlet part la, passes through the upper half 3a of a rotating heat exchanger rotor 3 (of a known nature in and of itself) equipped with axial through-flow passages, which flows out as waste air (A) through the outlet part lb of the channel 1, while outside air (U) flows into the inlet side 2a of the lower channel 2, passes through the lower half 3b of the heat exchanger rotor 3, which flows out as inflow air through the outlet part 2b of the lower channel 2, in which an afterheater 4 can be arranged. A fan 5 for outflow air is placed in the outlet part 1b and ensures air flow through the channel 1, normally for exhausting to fresh air outside the relevant room, while a fan 6 for inflow air is placed in the outlet part 2b, namely in the present case downstream of the reheater 4, and ensures therefore for air flow through channel 2 for blowing in supply air to the room in question. In the different inlet parts 1a, 2a there are arranged filters, 7 and 8 respectively, to capture solid contaminants in the different air streams.

The normally fairly warm outflow air F heats the walls of the heat exchanger rotor's 3 axial flow passages, and the heat energy thus supplied is transferred during rotation to the flowing through, normally colder outside air U through the rotor's lower half 3b. Below this, an efficiency of about 75% is usually achieved, so that the outgoing outside air from the lower half of the rotor 3b reaches a temperature that exceeds the temperature of the outside air by about 75% of the difference between the temperatures of the outflow air and the outside air. If, therefore, the outflow air F has a temperature of approx. 20°C and the outside air U in cold weather is approx. -20°C, the temperature of the inflow air T (before any reheating) will be approx. +10°C.

According to the invention, the heat exchanger's working function is monitored by sensing the temperature of the inflow air in the outlet part 2b using a temperature sensor Sl. When sensing a temperature for the inflow air that is below a predetermined temperature value, for example +10°C, which is lower than that which can be expected after normal heat recovery in the heat exchanger rotor 3, an alarm signal is emitted (using means not shown). In order for any alarm indication to be correct, even at extremely low outside temperatures, the temperature sensor S1 is suitably placed on the side of the outlet part 2a of the channel 2 where the axial flow passages in the rotor 3 first run into the channel 2. This is illustrated in Figure 2, where the arrow P indicates the direction of rotation of the rotor 3. At the inlet into the channel 2, the channel walls in the rotor 3 are quite hot, while during continued turning they gradually cool down, so that an outflowing inflow air acquires different temperatures, namely approx. +15°C at point A , about 10°C at point B and about +5°C at point C under the conditions stated above (exhaust air +20°C, outside air -20°C). When placing the temperature sensor Sl near point A, the lower temperature limit for alarms can thus be set at +10°C with a good margin for incorrect alarm indication at certain occurring outside air temperatures. However, this temperature limit should be chosen with sufficient consideration of the climate conditions that prevail in the relevant area where the heat exchanger is installed.

In the event that an afterheater 4 is arranged in the outlet part 2b of the channel 2, the temperature sensor Sl should be placed so that it is not significantly affected by radiant heat from the afterheater. It may be necessary to shield the temperature sensor Sl using a screen, as schematically indicated in Figure 1 by the dashed line 9.

Claims (7)

1. Method for operationally monitoring a rotary heat exchanger with two mutually adjacent channels (1,2) arranged for air flow in opposite directions, while a heat exchanger (3) equipped with actual flow passages is arranged with its one half (3b) placed in the one channel (2) and with its other half (3a) placed in the other channel (1), so that inflowing outside air (U) in one channel (2) after passing through the rotor (3) flows out as inflow air (T) , while the inflowing outflow air t (F) in the second channel (1) after passing through the rotor (3) flows out as waste air (A), with the operational monitoring taking place by temperature sensing, characterized in that only the temperature of the inflow air (T) is monitored, so that indication of an operational disturbance takes place if this temperature falls below a predetermined temperature value, for example +10°C, which is lower than that which can be expected after normal heat recovery in heat exchange the rotor (3). 2. Method as stated in claim 1, characterized in that the temperature of the inflow air (T) is sensed before it subsequently passes a reheater (4). 3. Device for operational monitoring of a rotating heat exchanger with two mutually adjacent channels (1,2) arranged for air flow in opposite directions, a heat exchanger rotor (3) equipped with axial flow passages being arranged with one half (3b) placed in the one channel (2) and with its other half (3a) placed in the other channel (1), so that inflowing outside air (U) in one channel (2) after passing through the rotor (3) flows out as inflow air (T) and inflowing exhaust air (F) in the second channel after passing through the rotor flows out as exhaust air (A), characterized in that a temperature sensor (S1) is arranged in said one channel (2b) on the downstream side of the rotor for sensing the temperature of the inflow air (T), while indicating means are arranged to emit an indication signal about operating disturbances if the sensed temperature of the inflow air falls below a predetermined temperature value, for example +10°C, and which is lower than that which can be expected after normal heat recovery in the heat exchanger rotor (3). 4. Device as stated in claim 3, characterized in that said temperature sensor (Sl) for the temperature of the inflow air is placed on the side of the center point of the channel (2b), namely on the side where the flow passages of the heat exchanger rotor (3) during rotation first run into the channel. 5. Device as specified in claim 3 or 4, characterized in that said temperature sensor (S1) for the inflow air is placed between the heat exchanger rotor (3) and an afterheater (4). 6. Device as specified in claim 5, characterized in that the temperature sensor (Sl) for the inflow air is positioned so that the afterheater's (4) heat beam influence on the temperature sensor (Sl) is of no importance. 7. Device as specified in claim 6, characterized in that a screen (9) is arranged to shield the afterheater's (4) heat radiation towards the temperature sensor (S1).