FI79810C - Heating and air conditioning system in a bus. - Google Patents

Description

1 79810

Bus heating and air conditioning system

The invention relates to a heating and air-conditioning system for a bus, which comprises an air intake duct, the air intake opening at one end of which opens to the outside of the vehicle and which supplies the intake air to the interior of the vehicle via a circulating water heat exchanger.

In known bus heating and air conditioning systems, the air intake is located at the bottom of the front of the car. In this case, the exhaust fumes of other traffic can easily enter the interior of the car, which can prove very embarrassing, especially in urban traffic. Exhaust air valves are usually located at the rear of the body to provide adequate air circulation in the passenger compartment. The air flows in 15 cabins from front to back for up to 12 meters. In this case, the old indoor air flowing backwards in the passenger compartment mixes with the supply air, which weakens the refreshing effect of the supply air. In addition, additional fans at the front of the car interfere with cabin airflows and further degrade air conditioning. In known solutions, changing the air according to the regulations 10 times per hour is often not enough to guarantee good air quality.

In known systems, the intake air is heated by a heat exchanger through which the engine coolant 25 circulates. The engine cooling system may be connected to a heat exchanger by means of a three-way valve, whereby the heat exchanger has a kind of its own liquid circulation, in which the temperature of the circulating liquid can be regulated by said three-way valve. This arrangement can be used to compensate for slow changes in ot-30 air or cabin temperature. However, rapid temperature changes with the arrangement cannot be corrected.

The object of the invention is therefore a heating and air-conditioning system for a bus, with which rapid temperature changes 35 can be corrected.

2 79810

It is also an object of the invention to improve air circulation in the passenger compartment.

This is achieved by a heating and air conditioning system of the type described in the introduction, characterized in that the system further comprises a preheat exchanger located in the air intake duct between the air intake and the heat exchanger, an exhaust air duct passing from the interior to the preheat exchanger, 10 in order to compensate for rapid temperature changes, the amount of intake air to be supplied from the air intake duct to the heat exchanger can be limited, if necessary, and exhaust air from the exhaust air duct can be introduced instead.

The air is preferably drawn in from above the windscreen, because there is the highest boost pressure and cleaner air than below the windscreen, from which the air is currently drawn in.

The indoor air is preferably removed by means of an exhaust duct terminating at the front of the roof, since the front of the roof has a maximum vacuum of 20 to provide stronger suction and better air circulation. The air flows are mainly directed from top to bottom, as fresh supply air is supplied to each passenger separately and exhaust air through the exhaust valves at the bottom of the passenger compartment to the exhaust duct, respectively. There are essentially no longitudinal currents in the passenger compartment. Good air quality is achieved even with less ventilation than required. The exhaust air passes through a preheat exchanger located in the air intake duct, releasing heat to the incoming air, thus avoiding separate auxiliary heaters if the required amount of heat from the engine coolant is not obtained for heating the bus. Below 60 ° C, the engine coolant is harmful to the engine and a lower temperature is no longer sufficient to heat the intake air properly. The Ke-35 slag preheat exchanger can be used as a precooler.

3 79810 when the air needs to be cooled mechanically.

Said control means can, if necessary, direct all the exhaust air back to the passenger compartment via the heat exchanger, for example when rapid temperature changes occur in the outside air 5 for which the circulating water temperature corrections are too slow to correct. Exhaust air recirculation also speeds up the warm-up of the passenger compartment before driving. Recirculation is preferred to maintain a sufficient temperature during and immediately after opening the door. When the door is open and the control flap is in the recirculation position, it is advantageous for the fan connected to the heat exchanger to operate at full power, so that air recirculation is accelerated and cold air flowing from the open door is quickly removed from the passenger compartment.

The invention will now be described in more detail by means of an exemplary embodiment with reference to the accompanying drawing, in which Figure 1 illustrates a side sectional view of a heating and air conditioning system according to the invention placed on a bus, and Figure 2 illustrates the electronic control system of Figure 1 in block diagram form.

As shown in Figure 1, the front of the bus has an air intake 1 in the upper part of the cab immediately below the roof, preferably in the longitudinal direction of the car, the front end of which opens in front of the car above the windscreen to form a funnel-shaped air intake 2. The air intake duct 3, which heats the intake air and feeds it into a distribution duct located at the top of the passenger compartment longitudinally of the car.

Below the air intake duct 1 there is a parallel exhaust air duct 4, the initial part of which forms a vertical riser 11, preferably starting from the luggage compartment under the passenger compartment 4 79. A preheat exchanger 5 is arranged between the air intake opening 2 and the heat exchanger 3. along. The exhaust air duct 4 terminates below the preheat exchanger 5, from where the exhaust air continues upwards along the vertical passages of the preheat exchanger 5, ending outside the preheat exchanger 5 through an outlet 6 in the roof outside the car. In this case, the warm exhaust air flowing through the preheater 5 heats the intake air passing through the air intake duct 1.

In the section between the preheat exchanger 5 and the heat exchanger 3, the bottom wall of the air intake duct 1, i.e. the partition between the air intake duct 1 and the exhaust air duct 4, 15 forms a control flap 7. The control flap 7 is articulated in the middle from a horizontal position in which it isolates the ducts from each other and directs the intake air to the heat exchanger 3 and the exhaust air to the preheat exchanger 20 to a vertical position where it directs the exhaust air to the heat exchanger 3. In the example case, the control flap 7 has two operating positions. With a different structure, the intake air and the exhaust air can also be directed as a desired mixture to the heat exchanger.

The control flap 7 is controlled in a manner to be described later on the basis of the measurement made with the temperature sensor 12.

At the beginning of the distribution channel 9, immediately after the heat exchanger 3 and the fan (not shown), a measuring flap 10 is placed, which is in the distribution channel 9 in a vertical position and transverse to the flow direction. The metering flap 10 is accelerated at its upper end so that the air flow from the heat exchanger can rotate the flap 10 vertically to an angle proportional to the flow rate or air pressure in the distribution duct 9. This angle of rotation is measured by a suitable sensor, e.g. (Figure 2). Based on this measured value, the control unit 21 shown in Fig. 2 adjusts the fan speed by means of a suitable motor control unit 25. In this way, the flow rate in the distribution channel 9 can be kept substantially constant regardless of changes in the boost pressure.

At the bottom of the distribution duct there are regular openings 14 in which the air between the fins is evenly distributed 10 throughout the passenger compartment. The fins are preferably tubes in which the engine coolant circulates, heating the air flowing past. Correspondingly, the lower part of the passenger compartment has openings 15 at regular intervals, through which the indoor air exits into the boot 16 and further through the exhaust duct 4 out of the car. The strong suction caused by the large vacuum at the outlet 6 at the front of the roof provides an efficient air circulation. If desired, the vacuum can be increased by a protrusion 18 at the front edge of the roof before the outlet opening 6.

The heat exchanger cell 3 can also be a double cell, in which case, in addition to the engine coolant, a coolant can also be circulated to cool the indoor air during the warm seasons. In this case, the cool exhaust air also cools the intake air in the preheat exchanger.

Figure 2 shows a block diagram of an electronic control system according to the invention. Connected to the control unit 21 is a temperature sensor 12, a potentiometer 22, a flap control 23, a three-way valve control 23 and a fan control 25.

A temperature sensor located after the heat exchanger 3, e.g. in the distribution duct 9, generates a measurement signal. Based on this signal, the control unit 21 controls the flap 8 and the three-way valve, which regulates the temperature of the engine coolant 35 circulating through the heat exchanger 3. As the measured temperature decreases rapidly away from the set value of 6 79810, the control unit 21 turns the control flap 7 to the vertical position. At the same time, the three-way valve is controlled so that the temperature of the circulating fluid begins to rise. The control flap 7 is turned to a horizontal position when a predetermined period of time 5 has elapsed (liquid temperature control delay) and / or when some other condition is met. During the opening of the door, the control unit 21 may be adapted to control only the control flap 7.

The potentiometer 22 generates a signal proportional to the atmospheric pressure acting on the measuring flap 10, on the basis of which the control unit 21 infinitely adjusts the fan speed.

The blocks of Figure 2 can be easily implemented with commercially available control circuits and units. Of course, the control system can also be implemented differently from the above.

The figures and the related explanation are only intended to illustrate the invention. The details of the heating and air conditioning system according to the invention may vary within the scope of the appended claims.

Claims (10)

A heating and air conditioning system in a bus or similar vehicle, which system comprises an air intake duct (1), at one end of which an air intake opening (2) opens outside the vehicle, and which feeds inlet air through a heat exchanger ( 3) of water circulation type to the interior of the vehicle, characterized in that the system further comprises a preheat exchanger (5) located in the air inlet duct (1) between the air inlet opening (2) and the heat exchanger (3), and an outlet air duct (4, 11), which likes to circulate from the interior spaces through the preheat exchanger (5) and opens outside the vehicle, and control means (7), by which the amount of intake air which is conducted from the air intake duct (1) to the heat exchanger (3) can, to compensate for rapid temperature changes, if necessary limited and outlet air can be routed in its place from the outlet air duct (4) in the corresponding way. 2. A system according to claim 1, characterized in that the control means comprise at least one flap (8) which in its normal position directs all the intake air to the heat exchanger (3) and all the exhaust air through the pre-heat exchanger and which prevents the intake air in a second position. permits the exhaust air to flow to the heat exchanger (3). 3. A system according to claim 2, characterized in that the control means further comprise control and measuring means (12, 21, 23) which control said flap (8) on the basis of the indoor temperature measurement. System according to any of the preceding claims, characterized in that the outlet air duct (4) starts at a luggage compartment (16) under the passenger compartment (11). System according to any of the preceding claims, characterized in that the air circulation type heat exchanger (3) has a double pipe laying, in which one of the engine's circulating air circulates, the intake air 11 is heated, and in the other of which kail fluid circulates, and the intake air should be cooled11. System according to any of the preceding claims, characterized in that the heat exchanger is connected to the engine cooling system by means of a three-way valve which is controlled by said control and measuring means. 7. A system according to any one of the preceding claims, characterized in that an air pressure sensor 10 (10, 22) is located after the fan of the heat exchanger (3), which generates a signal, on the basis of which the speed of rotation of the fan is controlled. 8. A system according to claim 7, characterized in that the pressure transducer is a flap (10) which is rotatable at the upper end, to which a shaft is connected a potentiometer (22), which produces a signal proportional to a turning angle as the air pressure increases. in the flap. 9. A system according to any one of the preceding claims, characterized in that the air intake duct (1) 20 is located in the upper part of the cab of the vehicle and that the air intake opening opens above the windscreen. System according to any of the preceding claims, characterized in that the outlet air duct (4) opens to the front of the roof of the vehicle.