EP0579074B1 - Baking oven with a cooling air fan and/or with a hot-air fan - Google Patents

Description

The invention relates to an oven with a heating element baking muffle and with a switch space provided outside the baking muffle for electrical or electronic components and with a cooling air blower arranged outside the baking muffle and / or with a hot air blower arranged inside the baking muffle.

In ovens, it is known to cool the surroundings of the baking muffle with fresh air generated by a cooling air blower and thus to protect the electrical and electronic components arranged in a switch room above the baking muffle from overheating. Furthermore, it is known to circulate the air heated by the heating element within the baking muffle in order to equalize it with a hot air blower.

DE-A-32 11 487 discloses a double oven in which the upper cooking space is heated with microwave energy, while the lower one is equipped with conventional radiators. A large number of electrical and electronic components are housed outside the cooking compartments, protected against overheating, without providing a special cooling fan. This is achieved in particular by the fact that cooling air is sucked in via an air inlet opening on the upper housing edge by a fan, which thus cools the magnetron and the electronic components of the control device. The fan motor driving this fan also puts another fan into operation for cooling the electrical components, such as a transformer. In contrast, another motor inside the lower cooking chamber drives a fan to circulate the heated air.

AC motors are used to drive these fans. The disadvantage of these AC motors is that they have to be dimensioned for the frequency or amplitude of the mains voltage present. If devices are delivered to countries with different mains voltages, the appropriate motor must be installed in advance. This requires the provision and assembly of different engine types, which complicates the manufacture considerably.

The invention therefore presents the problem of creating an oven in which these disadvantages are avoided and universally usable cooling air and hot air blower motors can be used.

According to the invention, this problem is solved by an oven with the features of claim 1. Advantageous embodiments of the invention result from the following subclaims.

The advantages that can be achieved with the invention are that the fan motors are independent of the amplitude and frequency of the respective mains connection voltage can always be operated with the same supply voltage. Another advantage is the considerably simplified speed control of these motors, as there is no need for expensive AC power controllers.

In a particularly advantageous embodiment of the invention, the fan motors are operated with a low voltage of less than 42 volts, in particular 12 or 24 volts. This eliminates the approval required for motors operated with higher supply voltages.

Furthermore, due to the possible use of low-voltage motors in herds, the same motor types can be used for all target countries during production, which has a particularly favorable effect on warehousing.

The use of a controllable cooling air blower, depending on the set or actually existing baking muffle temperature, results in considerable energy savings of around 5%.

Figur 1

die schematische Darstellung eines Backofens im Querschnitt;

Figur 2

die Funktionsweise der elektrischen und elektronischen Bauteile in Blockschaltbilddarstellung.

An embodiment of the invention is shown purely schematically in the drawings and is described in more detail below. Show it:

Figure 1

the schematic representation of an oven in cross section;

Figure 2

the functioning of the electrical and electronic components in block diagram representation.

The oven in Figure 1 has a baking muffle (1), which is closed at the front by a door (2). There is an air inlet opening (3) in the area below the door (2) and an air outlet opening (4) in the handle area of the door (2). These are connected to a cooling air duct (5) arranged around the baking muffle (1).

A crossflow fan (6) inserted in this channel (5) serves as a cooling air blower. It is connected on the suction side to the air inlet opening (3) and on the pressure side to the air outlet opening (4) via the upper area of the cooling air duct (5), the latter separating the baking muffle (1) itself and the overlying switch space (7) of the oven. The blown out cooling air serves on the one hand for thermal insulation the baking muffle (1), on the other hand, via a vapor extraction duct (8), it dissipates the cooking fumes generated in the baking muffle (1) to the outside. The cross-flow fan (6) is driven by a fan motor (9) on the side.

In the switch room (7) are the electrical and electronic components for operating the oven and for the dependent control of the consumers. In the rear area of the switch room (7) there is a connection strip (10) via which the oven is supplied with mains voltage. The entire control electronics (11) are located in the front area behind the control panel. This is electrically connected to selector switches (12) for selecting the baking muffle temperature and the type of heating, as well as the sensor for measuring the baking muffle temperature actually present. A temperature sensor (13) is arranged inside or in the vicinity of the control electronics (11).

The baking muffle (1) is heated by an upper heat radiator (14), a lower heat radiator (15) and a ring radiator (16). The blower wheel (17) of a hot-air blower is arranged inside the ring heating element and serves to evenly distribute the heat generated in the baking muffle (1). The drive motor (18) of the hot air blower is fastened outside the baking muffle (1) on its rear side (19).

Figure 2 shows the operation of the electrical and electronic components using a block diagram. A primary-clocked switching power supply (20) generates two direct voltages of 12 volts and 24 volts, which are independent of the amplitude and frequency of the mains voltage. The 12 volt voltage is used to supply small consumers and relays (not shown in the drawing) and, after transformation to 5 volts, to supply the control computer (21).

The 24-volt voltage is applied to the fan motor (9) and the drive motor (18) of the hot air blower via current valves (22a; 22b). Both motors (9; 18) are collectorless DC motors that work on the external rotor principle. The control computer (21) opens and closes the current valves (22a; 22b) and thus influences the engine speeds. The stator windings are commutated via Hall sensors. If the control computer (21) detects a rotor standstill, ie no change in the magnetic field, then it detects a failure of the cooling or hot air blower and switches off the radiators (14; 15; 16).

The speed of the cooling air fan is controlled continuously depending on the ambient temperature measured with the temperature sensor (13) on the control electronics (11) and depending on the type of heating set using the selector switch (12), but also depending on the type set in the baking muffle or existing temperature. In this way, on the one hand, the components of the control electronics (11) are protected against overheating, and, on the other hand, excessive cooling of the baking muffle can be prevented by the cooling fan being too powerful.

The stepless control of the hot air blower speed is only dependent on the type of heating set with the selector switch (12) in connection with the previously selected or actually existing temperatures in the baking muffle.

Claims (10)

1. Baking oven, having a baking muffle (1) provided with heating elements (14, 15, 16), and having a switch chamber (7) provided externally of the baking muffle for electrical or electronic component parts, as well as having a cooling air fan (6) disposed externally of the baking muffle, and/or having a hot-air fan (17) disposed internally of the baking muffle, characterised in that the drive of the hot-air and/or cooling air fan (17, 6) is effected in each case by a low-voltage motor (9; 18), which is constantly operable with the same supply voltage independently of the frequency and amplitude of the respective mains voltage.
2. Baking oven according to claim 1, characterised in that a primary set switching power pack (20) supplies a direct voltage which is independent of the frequency and amplitude of the mains voltage connected to the baking oven.
3. Baking oven according to one of claims 1 or 2, characterised in that the direct voltage supplying the low-voltage motors (9; 18) is preferably 12 or 24 volts, but it is always less than 42 V.
4. Baking oven according to one of claims 1 to 3, characterised in that the low-voltage motors (9; 18) are commutatorless direct-current motors.
5. Baking oven according to claim 4, characterised in that the commutatorless direct-current motors (9; 18) operate according to the external rotor principle.
6. Baking oven according to one of claims 1 to 5, characterised in that the commutation of the stator windings is effected by means of control elements which are sensitive to magnetic fields, more especially by means of Hall sensors.
7. Baking oven according to one of claims 1 to 6, characterised in that a stepless speed setting is effected for the hot-air fan (17) in dependence on the selected type of heating of the baking oven.
8. Baking oven according to one of claims 1 to 7, characterised in that a stepless speed setting is effected for the hot-air fan (17) in dependence on the temperature actually existing or previously selected in the baking muffle.
9. Baking oven according to one of claims 1 to 8, characterised in that the cooling air fan (6) is controllable, and a stepless speed setting is effected in dependence on the temperature in the switch chamber and on the set type of heating.
10. Baking oven according to one of claims 1 to 9, characterised in that the cooling air fan (6) is controllable, and a stepless speed setting is effected in dependence on the temperature in the baking muffle.

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