FI66484C - VENTILATIONSFOERFARANDE OCH -ANLAEGGNING - Google Patents

Abstract

1. Method for ventilation, particularly of large rooms, such as workshops and industrial halls, wherein the supplied air, controlled depending upon the room temperature, is supplied mainly from above downwards characterized in that the supplied air is delivered in the form of impulses and the impulse flow of the supplied air is controlled, on the basis of the temperature difference between the temperature in the upper part of the room and the temperature in the lower part of the room in such a way that if the temperature difference exceeds a predetermined value the impulse flow of the supplied air for maintaining the desired temperature distribution in the room is increased so that the projected distance of the supplied air reaches into the lower personnel area.

Description

ι 66484

Air conditioning method and equipment

In a climate such as Finland, the air conditioning of rooms, especially large rooms, such as factory halls, is also closely related to space heating. Warm air leaks out of the upper parts of the buildings, cold air leaks in from the lower parts. The temperature difference between the upper part of the room and the working level becomes considerable and maintaining a sufficient temperature in the working level thus incurs considerable costs.

The method according to the invention is characterized in that, for example, DE application publication 2 919 703 and F1 patent application 77 3852 have a supply air from top to bottom in a known direction so that the air jet draws 15 side air with it. However, simply directing the supply air from top to bottom with a predetermined impulse, in accordance with the teaching of the above-mentioned publications, is not a sufficient measure, since the throw length of the supply air jet is considerably shortened as the temperature of the air jet rises. In order to ensure the desired temperature 20 at the working level, the impulse of the supply air has to be oversized, resulting in disturbing traction and energy loss throughout the time when even a smaller impulse would be sufficient.

The invention thus relates in particular to a method for ventilating large rooms, such as workshops and industrial halls, in which the supply air is directed at least substantially downwards from above, and to eliminate the disadvantages of known solutions so as to efficiently utilize .

To achieve this, a method is proposed which is mainly characterized by adjusting the supply air flow pulse based on the temperature difference between the upper and lower part of the room to be ventilated, so that when the temperature difference exceeds a predetermined value, the desired .

Preferably, the method is implemented by increasing the pulse of the supply air flow in proportion to the observed temperature difference. In this way, the temperature difference, which can be, for example, 1 to 3 ° C, is kept constant within a predetermined permissible temperature difference. This measure, which seems natural in itself, achieves the desired result only in combination with the supply air impulse control according to the invention.

10 On the other hand, the somewhat approximate heating of the supply air to date has often led to the opposite result when sought.

The invention also relates to an apparatus for carrying out an air conditioning method comprising a supply air device 15, a supply fan, a heating device located in front thereof, an outdoor air flow control device and a recirculating air control device and a working level temperature sensor for controlling said control devices and heating device, is located at the top of the air-conditioned room and is directed at least substantially downwards.

The apparatus is characterized in that temperature sensors are arranged in the upper and lower part of the room, which are connected to a common controller, that a supply air flow control device is connected to the controller and that the controller is adapted to act on the supply air flow control device. the pulse of the supply air flow of a predetermined value increases.

The invention will now be described in detail with reference to the accompanying drawing, which shows a cross-section of a building to be ventilated and in which the apparatus according to the invention is schematically drawn.

The building to be air-conditioned is marked with the reference number 21 35 and can be, for example, a workshop or other industrial hall. For air conditioning and heating at the same time, 3 66484 air is used both outside air 19 and recirculated air 20 from inside the room. These airflows are controlled by known control devices 1 and 2 in a manner which will be explained in more detail below. A filter 3, a heating coil 4, a fan 9 and a supply air device 12 are arranged in the supply air duct. The supply air device 12 is located in the upper part of the room to be ventilated and is directed downwards.

The controller 14 controls the temperature control device 1 and 2 on the one hand via the actuator 13 and on the other hand the heating coil 4 via the actuator 5 and the valve 6 on the basis of the signal from the sensor 15.

In addition, temperature sensors 16 and 17 are located in the lower and upper part of the room, which give 15 signals to the controller 18. Based on the temperature difference between the upper and lower room, the controller 18 regulates the supply air flow, for example by means of an actuator 11 the power of the fan 9 by means of the control member 20 7 via the actuator 8, the connection b. The members 10, 11 and 12 can be coordinated and the pulse control of the supply air flow can be realized by increasing the air flow but also by changing the supply air device 12 Respectively, the members 7, 8 and 9 may form 25 common units. There can, of course, be several supply air devices 12, as well as temperature sensors 16 and 17 and controllers 18.

The cooling coil 22, the heating coil 23 and the fan 24 can form a separate recirculating air unit 30 which can be operated in parallel with the recirculating air intake 20 and whose operation as well as this can be adjusted by means of a controller 14.

The minimum airflow of the system and the supply air unit is dimensioned according to the ventilation need of the room.

35 In a situation where the room air temperature is to enter the area, ie in a situation where there is no need to create heating capacity in the room or remove excess heat from it, the aim is to keep the room air at the ceiling, eg approx. 1 - 3 ° C warmer than in the living area at floor level and then the supply air temperature must be the same as prevailing at floor level, ie isothermal.

5 The supply air device pulse (mass flow x speed = minimum air flow x output speed at the supply air device opening) is selected so that its throw length extends to the top of the living area.

When the temperature difference measurement (or otherwise found-10 tu) on the sensors 16 and 17 shows the difference greater than the target and the temperature level measurement at point 15 indicates the need for heating power, i.e. the room air temperature is below the target level, the temperature controller 10 proportionally increase the airflow, whereby (option a) the pulse of the supply air device (mass flow x speed) increases, increasing the throw length of the supply air device, which would otherwise decrease as the temperature between the upper and lower part of the room increases. This increases the ability of the supply air unit indu-20 to ring and bring process heat accumulating to the ceiling to the living area and utilize it for heating purposes. If there is only one temperature difference controller 18 in the room, the control command of the controller is directed directly to the fan 9, to the power control device 7 (option b).

25 As the total airflow in this case increases, the control dampers 1 and 2 of the instrument increase the recirculated airflow 20, keeping the outdoor airflow 19 in line with the ventilation demand while the temperature controller 14 keeps the supply air temperature desired = setpoint in the sensor 30 15.

When the room air temperature at the sensor 15 further decreases, the controller 14 starts to increase the supply air temperature with respect to the temperature deviation from the set value by increasing the heat through the radiator 4 and its motor valve 6 and the operating device 35. As the supply air temperature rises above the room air temperature, the throw length of the supply air device 12 is shortened and the temperature difference in the sensors 16 and 17 increases as a result of the controller 18 further increasing the supply air flow rate and pulse. The maximum air flow of the supply air device and thus the maximum speed in the blower opening is selected in a situation where the heating power demand 5 of the room is at its maximum, i.e. both the supply air temperature and the volume flow are at a maximum. This is also technically possible in practice when selecting a supply air device whose blower size is adjustable.

In a situation where the room air temperature rises too high, i.e. exceeds the target level, a supply air colder than the room air temperature is introduced into the room. The system then uses a separate supply air system 22, 23 and 24 or the supply air of the existing system derived therefrom, in which the control of the power parameters, i.e. the temperature and air flow of the supply air, and the air distribution take place using conventional known technology.

The system preferably also uses conventional known heat recovery methods.

In a larger system, i.e., a system 20 that includes multiple temperature differential controllers 18, the need for fan work is minimized by using the desired minimum static pressure required in the supply air duct as the fan power control variable.

During the heating season, only as much outdoor air is used as is required for ventilation. The total air flow used for heating power distribution is the smallest possible, ie the energy demand for blowing work is minimized.

The heat generated by the process (e.g. lighting, machinery, people and also passive solar heat) is utilized 30 primarily before moving on to the so-called for the use of thermal energy for a fee.

Claims (6)

6 66484 A method for ventilating large rooms in particular, such as workshops and industrial halls, wherein the supply air is directed from above at least substantially downwards, characterized in that the supply air flow pulse is adjusted based on the difference between the upper and lower temperatures The pulse of the supply air flow is increased to maintain the desired temperature distribution in the room space. Method according to Claim 1, characterized in that the pulse of the supply air flow is added in proportion to the detected temperature difference. Method according to claim 1 or 2, characterized in that the heating of the supply air is increased when the temperature difference is at most equal to said predetermined value and the temperature at the bottom of the room is below another predetermined value. An apparatus for carrying out the method according to claim 1, comprising a supply air device (12), a supply fan (9), a heating device (4) placed in front of it, an external air flow control device (1) and a recirculation air control device (2) and a space 25 at the bottom. a temperature sensor (15) for controlling (14) said control devices (1 and 2) and the heating device (4), the supply air device (12) being arranged at the top of the room to be ventilated and directed at least substantially downwards, characterized in that temperature sensors (17, 16) are connected to the lower part, which are connected to a common controller (18), that a supply air flow control device (7, 10) is connected to the controller (18), and that the controller (18) is adapted to act on the supply air flow control device (7). , 35 10) the temperature observed in the upper and lower part of the room on the basis of the difference so that when the temperature difference exceeds a predetermined value for the supply air flow n impulse increases. 7 66484 Apparatus according to Claim 4, characterized in that the supply air flow control device (10) is arranged in front of the supply air device (12). Apparatus according to Claim 4, characterized in that the supply air flow control device (7) is arranged in front of the supply air flow fan (9). 8 66484