HU184644B - Bus provided with heating and ventillating device - Google Patents

Abstract

The method is intended to eliminate wrong decisions by an operator in the heating and aerating of a bus and to permit optimum aeration and air-conditioning of the interior of the bus. This is achieved in that the driver's compartment and the passenger compartment are separately supplied with air, the driver's compartment being aerated via at least one front air inlet and the passenger compartment being aerated via at least one air inlet located in the rear region of the side walls or of the roof and the two compartments being vented via at least one joint air outlet arranged in the low-pressure region, which is established when driving, of the front end of the bus, and in that when a central switch is switched on the passenger compartment is heated under the control of a thermostat whereas the heating of the driver's compartment is manually controlled.

Description

The present invention relates to a bus equipped with a heating and ventilation device.

It is known that bus cab and cabin are generally heated and ventilated together. The buses therefore have openings at the front which allow air to flow through the passage. Some of the air is flowing into the windscreen and into the cab, the other into the passenger compartment. Circulation is done by means of nozzles. The interior of the car bus is heated by recessed heaters on the one hand and a so-called heater on the other. The heater is located at the front of the bus near the air intakes. The bus driver centrally controls the heater and the heaters.

This heating and ventilation has significant disadvantages. The management of heating and ventilation systems distracts the driver from his main task, driving. You can't focus entirely on leadership. From the stationary seat, the driver is unable to check and adjust the cabin temperature and air. The heating and ventilation equipment is often misadjusted because it feels like it is adjusting to the cab conditions. For example, if the driver is sitting in the sun, the heater is unlikely to turn up, while it would be nice for passengers in the shade.

Further, it is a disadvantage that with this known ventilation, the air contaminated with the exhaust gas is sucked in directly and introduced into the passenger compartment.

The interior of the buses is cooled in the same way as the ventilation and heating, as the driver operates the chiller at his own discretion.

Improper ventilation and heating of the interior is a nuisance for passengers, while poor ventilation is extremely harmful. Improper handling of the heating and ventilation system often causes a cold to the occupants.

The "Heizungs-, Lüftungs-, Haustechnik" (Heating, Ventilation, Home Appliances) 12, 1959, pages 338-341. pages 3 to 9 describe the pressure zones formed on the outer surface of the vehicle as it travels and the effect of these pressure zones on the interior airspace of the bus. According to the authors of the article, taking into account the flow conditions of the interior airspace of the bus, the warm air must be predominantly located in the rear of the vehicle.

No. 350,603. The English patent also provides guidance on how to introduce air into the interior air space of the bus, but does not address in sufficient detail how the introduced air leaves the interior of the bus.

It is an object of the present invention to provide an apparatus for heating and ventilating the interior airspace of buses, thereby eliminating the subjectivity of the operator by providing optimal ventilation and heating of the interior airspace of the buses.

The object of the present invention has been accomplished by providing a bus equipped with a heater and venting device which has a cab, cabin, roof area, sidewalls, floor, side windows, front and rear air inlet and outlet, heat exchangers, switchable nozzles and a control and control device provided with a central switch, wherein at least a portion of the nozzles is connected to a heat exchanger and the control and control device is connected to at least a portion of the heat exchangers.

An improvement of the present invention is that the control and control device is connected to nozzles associated with the passenger compartment, at least a portion of which are provided with a temperature regulator, and at least one heat exchanger or nozzle associated with the passenger compartment and heat exchangers independent of the passenger compartment. it is provided with a manual control, preferably a manual valve connected to the heat exchanger and located in the piping system, as well as a switch connected to the nozzle.

The above design allows the cabin and the cabin to be independently ventilated by heating the cabin with temperature control and the cabin with manual control.

Preferably, the air conditioner is provided with at least one refrigerant-carrying evaporator, compressor, and condenser, which are connected to the duct system, the evaporators being at least part of the nozzles! they are connected; and further comprising a second control and control device having a central switch and having at least one temperature controller, which is mounted on the compressor! and connected to the nozzles.

In addition to heating and ventilating the bus, this embodiment also allows cooling of the bus.

It is also preferred that the heat exchangers are provided with control valves located in the piping system, some heat exchangers together with their associated nozzles are designed to be fully thermostatically controlled heater and recessed below the floor of the bus, while the other

Further, it is advantageous to have air inlet and outlet openings in the form of lockable slots with controllable covers, which are arranged above the side windows of the bus and are in communication with the passenger compartment. The slots, which can be closed with lids, fit well into the appearance of the bus and are located at a height where relatively unused air can be sucked in. With adjustable covers, the slots can be partially or completely closed, making it easy to control the inflow and outflow of 3 fresh air.

Preferably, the heat exchangers and nozzles located in the roof region are connected to the air inlets at the rear of the bus sidewall, and the air inlets at the front of the bus sidewall are connected to the regulating and control devices.

It is further preferred that at least a portion of the lids is connected to the control and control device. In this way, proper programming of the control and control equipment ensures that the lids are always in the desired position. For example, if it is desired to heat, it is sufficient to ventilate the air inlet and outlet, while the other slots can be closed with the aid of lids.

It is also advantageous if the evaporators are arranged in the roof area, at the air intake openings above the side windows of the bus, and when the roof 21

Heat exchangers and evaporators in 184,644 ranges are interconnected.

BRIEF DESCRIPTION OF THE DRAWINGS Hereinafter, a bus equipped with an air conditioner according to the invention will be described in more detail with reference to the accompanying drawings, in which like parts are designated by like reference numerals

Fig. 1 schematically illustrates an embodiment of the heating and ventilation cavity according to the invention,

Figure 2 is a schematic view of another embodiment of the heating, ventilation, and air conditioning apparatus of the present invention;

Figure 3 is a cross-sectional view of the bus according to Figure 4, and Figure a.

Figure 4 is a side view of a bus 15 provided with the apparatus of the invention.

Fig. 1 shows a heating and ventilating device 1 having two conduit systems, a conduit system 2 for a heating medium and an electrical conduit system 3 for a thin line. The conduit system 2 is configured as a two conduit system. Each of the tubing branches 4 and 5 (not shown) is connected to the cooling water circulation of the drive motor and extends from the drive motor in the bus's tail to the nose (indicated by the opening P in Fig. 1) along the entire length of the bus. .

There is a so-called heating cabinet for heating and ventilating the cab, which is provided with a heat exchanger 6 connected to the pipe branches 4 and 5, which is connected to a snow exchanger 6 by a nozzle 7. Both parts are connected to the air inlet on the nose of the bus 3C, as shown in Figure 4. Figure 1 also shows a nozzle 7 and a switch 8, which switch 8 can be used to switch the nozzle 7 in two steps. For continuous control of the heat exchanger 6, a hand valve 9E is provided in the inlet pipe branch 4 of the conduit system 2. The driver can use the switch 8 and the manual valve 9 to set the desired heating or ventilation of the cab and windscreen.

As shown in Figure 1, heat exchangers 10 and 11 are provided for the passenger compartment. The heat exchangers 10 are coupled to the nozzles 12C in the form of recessed heaters located at the front of the bus. The heat exchangers 11 are provided with two nozzles 13 and are located in the top of the side walls in the roof area of the bus. 4i

Each heat exchanger 10, 11 is connected via the inlet line 14 to the inlet pipe branch 4 and through the outgoing pipe 15 to the outgoing pipe branch 5. The heat exchangers 10 serve to heat the air in the passenger compartment, while the heat exchangers 11 are preferably used to heat the fresh air introduced.

A water pump 16 is provided in the inlet pipe branch 4 for circulating the heating medium. In addition, a preheater 17 is provided in the inlet pipe branch 4 in case the cooling water circulation is not yet suitable for heating. because the engine is too cold, for example.

As shown in Fig. 1, further nozzles 18 are provided on both sides of the bus ahead of the nozzles 13 in the direction of the arrow P for ventilation and air circulation θ ¹ . These nozzles 13, like the nozzles 13, are also arranged at the side walls in the roof area of the bus.

Figure 2 shows that a grid 20 is provided throughout the side windows 19 of the bus, behind which are inlet and outlet air openings θ. These openings can be closed by the covers 21, 22 and 23 shown schematically in Figure 1. The lids 21 are associated with air exhaust openings, while the lids 22 and 23 are associated with air inlets.

The electrical wiring system 3 is shown in Figure 1 only with a circuit diagram, since the remainder of the system is located above the chassis in a manner known to motor vehicles.

At the driver's seat, a central switch 24 is disposed near the switch 8 for central control of the passenger compartment heater. You can see i. 10a, the nozzles 12 and 13 are directly connected to the electrical conduit system 3. In order to gradually regulate the power of the nozzles 12, for example from zero to 1/1, temperature regulators 25 are arranged in pairs. For smaller buses, a single temperature controller 25 can be used to control each lower recessed heater. The nozzles 18, as shown in dashed lines, are connected to the electrical system 3, and these nozzles 18 are not for heating but for ventilation.

Referring to Fig. 1, the nozzles 12 have an outlet side and two; one of the adjacent nozzles 13 has a temperature control sensor 26 (not shown) which is always connected to the control valve 27. Each of the control valves 27 is located in the inlet conduits 14 to the heat exchangers 10 and 11, respectively, which are used to continuously regulate the power of the heat exchangers 10 and 11, respectively.

Figure 3 shows a bus traveling in direction P. The air flows inside and outside the bus are indicated by arrows, where the arrows inside the bus illustrate the air flow when the heater is on.

The air collides with the nose 28 of the bus and, in the form of a schematic nose wave 29, strokes the forward bus. The plus and minus marks along the side walls illustrate the pressure there. At the beginning of the bus, there is low pressure in the region of the nose wave 29, on the side and on the roof 30. This range extends approximately to the rear edge of the first 19 side windows of the passenger compartment. The sidewalls and the rest of the roof are in the overpressure range.

In accordance with the present invention, utilizing the aerodynamic capabilities described above, the cabin and the cab can be separately heated and ventilated.

As mentioned above, behind the grid 20 located above the side windows 19 in Figure 4, longitudinal slots are formed in the body which can be closed by the covers 21, 22 and 23 shown in Figure 1. The slots behind the grid 20 are divided into three regions 31, 32 and 33. Areas 32 and 33 include air inlets, while area 31 serves for optional ventilation of the interior of the bus. Province 33 provides forced ventilation and in most cases remains open. Through the area 31, air from the passenger compartment and cab is vented, while air enters the cab through an inlet 34 at the nose of the bus.

Figures 3 and 4 show the path of air entering the inlet 34 from the driver to the windscreen or cab respectively.

-3ί 84,644

Thus, the cab is supplied with air through the inlet 34 while fresh air enters the passenger compartment through the region of the air inlets 33. The air outlet, that is, the ventilation of both spaces, is provided through the common air outlets 31 in the region 31 so that the air entering the bus nose 34 at the inlet 34 immediately exits through the common air outlets without exiting to a greater extent. would be

Figure 3 schematically shows the bottom of the bus with the central lane. A total of four lower recessed heaters 35 are shown, two of which are positioned adjacent to one another. These heaters 35 are provided with heat exchangers 10 and nozzles 12 and sensors 26 as shown in FIG. During operation of the nozzles 12, the air is drawn from the central passageway in the direction of the arrow P and discharged along the sidewalls in the heating channels 36. The heating ducts 36 are provided with openings through which the heated air flows obliquely backward into the passenger compartment. In the region of the first row of seats, air flows forward obliquely, as the lower recessed heater 35 is positioned above the wheels and the first row of seats is located in front of the wheels.

Inside the bus, the natural airflow provided by the air inlets of the region 33 and the air outlets of the region 31 and the inflated heated air are superimposed. As a result, the interior is supplied with evenly heated air.

The lids 21 shown in Figure 1 are disposed in the region 31 of Figure 4 to close the air outlets, while the lids 22 are in the region 32 with the nozzles 18 and the lids 23 in the region 33 with the heat exchangers 11 and nozzles 13.

The process of heating and ventilating the bus according to the invention, more particularly the bus shown in Figures 1, 3 and 4, will now be described.

During normal operation, the lids 23 and 21 are fully open except, for example, for washing the bus when closed.

If the driver only wants to heat the cab, he adjusts the manual valve 9 (manually) to determine the heat output of the heat exchanger 6. By means of the switch 8, the nozzle 7 can be switched into stages, thereby supplying hot air. Optional hot air can be directed to the cab space and to the windscreen. Immediately upon exhaustion of the air thus obtained, it flows into the open air through the air outlets in the region 31.

The cabin is heated by actuating the central switch 24. Operation of the central switch 24 is at the discretion of the driver, but further heating of the passenger compartment is already controlled by the control device.

The regulators for the sensors 26, not shown in Figures 1 and 2, and the temperature regulators 25 are set to predetermined values. If the actual temperature deviates from the set value, the nozzles 12 will switch to the first or second stage, depending on the degree of deviation. According to the value measured by the sensors 26, the control valves 27 open so that the power of the heat exchangers 10, 11 is adjusted according to the requirements. If the actual temperature is the same as that set, neither the nozzles 12, 13 nor the heat exchangers 10, 11 will operate. This applies not only to the heat exchangers 10 of the lower recessed heaters, but also to the heat exchangers 11 in the roof region, the power of which can be controlled by the control valves 27 in the siren.

In contrast, when the central switch 24 is actuated, the nozzles 13 operate automatically at half power.

If the driver wishes to ventilate the cab, natural airflow through the air vents on the nose of the bus is provided, which can be further increased by the use of stepwise nozzles 7. The fresh air thus obtained is discharged through air outlet openings located in the region 31 in a manner similar to warm air. If the driver also wishes to ventilate the passenger compartment, an additional ventilation switch 0-1 / 2-1, not shown, is provided. At position 0, the covers 22 in the region 32 are closed while the passenger compartment heater 21 is closed. , 23 covers open.

When the above ventilation switch is set to 3/2, the nozzles 13 and 18 in the roof area operate at half power. At this position of the ventilation switch, all covers 21,22, 23 are fully open.

When the driver sets the ventilation switch to full power, the nozzles 13 and 18 are fully powered and the lids 21, 22 and 23 are fully open. The ventilation switch is secondarily connected, i.e. when the switch 8 and the ventilation switch are operated simultaneously, the lids 22 close automatically and the other connections are superimposed without collision, which means that the nozzles 13 and 18 operate according to the position of the ventilation switch.

Lids 21, 22 and 23 can be closed when the bus is being washed.

Figure 2 shows the heating, ventilation and air-conditioning equipment lb. The structure of this device is essentially the same as that of FIG. . Therefore, like parts are designated by the same reference number.

To avoid unnecessary repetition, we will confine ourselves to describing the differences between the two embodiments. In addition to heating and ventilating the bus, this design is also suitable for cooling. Another difference is that two heat exchangers 11 are located under the roof per side wall, one of which is located at the rear of the side walls. The covers 22 are provided with heat exchangers 11. The heat exchangers 11 have four nozzles 13. The heat exchangers 10 serve to heat the air when lowered, while the heat exchangers 11 heat the air in the space or fresh air.

The heat exchangers 11 form a unit in which evaporators 37 of the bus air conditioner are also integrated. These evaporators 37 are connected in a non-illustrated manner to the compressor and capacitor located near the drive motor via the conduit system 2, here are other known and not shown parts of the air conditioning system, such as fluid storage, dryer, etc. also placed.

The electrical system of the refrigeration system is also not illustrated, but similar to the heating control. The driver is provided with a central switch 24 for cooling and air conditioning

Up to 184,644 units can be controlled and controlled. At least one temperature regulator 25 is located in the roof region which, in the event of a difference between the set and actual temperatures, switches on the compressor in stages and also gradually controls the nozzle 13 which operates the evaporator 37. By switching on the refrigeration and air conditioning system, each cover 21, 22, 23 is automatically placed in a half-covering position of the cross-section of the air inlet and outlet. 10

Claims (9)

PATENT CLAIMS An automobile bus 15 having a heating and ventilating device having a cab, passenger compartment, tea space, sidewalls, floor, side windows, air intake and outlet openings in the body of the bus, the system operatively connecting the heating medium, heat exchangers, switchable nozzles and a control and control device with a central switch, wherein at least a portion of the nozzles are connected to a heat exchanger and the control and control device is connected to at least 25 parts of the heat exchangers, characterized in that the control device is connected to the nozzles (12, 13) associated with the passenger compartment, the nozzles (12, 13) being provided with at least a portion of the thermostat (25), at least one heat exchanger (30) assigned to the cab and (6) and nozzle (7) with manual control independent of heat exchangers (10, 11) or nozzles (12, 13) assigned to the passenger compartment, preferably with a hand valve (9) connected to the heat exchanger (6) and located in the duct system (2); the nozzle (7) is provided with 35 switches (8). Bus according to claim 1, characterized in that at least one refrigerant conveying evaporator (37), a compressor and a condenser are connected to the conduit system (2) 40, the evaporators (37) being nozzles (37). 13) they are connected to at least a part thereof; and further comprising a second control and control device provided with a central switch (24) and having at least one temperature controller (25) connected to the compressor and the nozzles (13). Bus according to claim 1 or 2, characterized in that the heat exchangers (10, 11) are provided with control valves (27) located in the conduit system (2), some heat exchangers (1) with their associated nozzles (12). it is designed as a fully thermostatically controlled heater and recessed below the bus floor, while the other heat exchangers (11), together with their associated nozzles (13), are located in the roof area of the bus. 4. Bus according to any one of claims 1 to 4, characterized in that the air inlet and outlet openings are in the form of slots with controllable covers (2t, 22, 23) arranged above the side windows (19) of the bus and communicating with the passenger compartment. Bus according to claim 4, characterized in that the heat exchangers (11) and nozzles (13) located in the roof region are connected to the air inlets at the rear of the bus side wall. Bus according to claim 4 or 5, characterized in that the air inlets at the front of the side wall of the bus are provided with nozzles (18) connected to a control and control device. 7. Bus according to any one of claims 1 to 4, characterized in that at least part of the covers (21, 22, 23) is connected to the control and control device. 8. · A 2-7. Bus according to any one of claims 1 to 3, characterized in that the evaporators (37) are arranged in the roof area at the air intake openings above the side windows (19) of the bus. Bus according to claim 8, characterized in that the heat exchangers (11) and evaporators (37) located in the roof area are interconnected.