• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a cooking field device (10), in particular, to an induction cooking field device, with one or more heating units (12) having at least one heating conductor (14) which it is intended to heat a cooking battery (24) supported on it. In order to provide a generic cooking field device with lower costs, it is proposed that, in at least one plane of the cross-section, the heating conductor (14) present partially or in its entirety an approximate or exactly shaped conformation channel. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2573125A1
    申请号:ES201431794
    申请日:2014-12-04
    公开日:2016-06-06
    发明作者:Jesús ACERO ACERO;Sandra Aranda Vázquez;Claudio Carretero Chamarro;Cristina DÍEZ ESTEBAN;Pablo Jesús Hernández Blasco;Ignacio Lope Moratilla;Ricardo Ramos
    申请人:BSH Hausgeraete GmbH;BSH Electrodomesticos Espana SA;
    IPC主号:
    专利说明:

    image 1 INDUCTION COOKING FIELD DEVICE WITH HEATING UNIT DESCRIPTION
    The invention refers to an induction cooking field device with one or 5 several heating units having at least one heating conductor that is intended to heat a cooking battery resting on it.
    From the state of the art a cooking field device is already known which has a heating unit for heating a cooking battery. The heating unit has several heating conductors, each of which leads in a
    10 heating operating state a part of the total electric current flowing through the heating unit, and which are made as braided filaments.
    The invention solves the technical problem of providing a generic cooking field device with lower costs. According to the invention, this technical problem is solved by means of a cooking field device with one or more heating units having at least one heating conductor that is intended to heat a cooking battery resting on top, where, in at least one plane of the cross-section, the heating conductor partially or completely presents an approximate or exactly channel-shaped conformation. The term "cooking range device" includes the concept of at least one part, namely, a construction subgroup, of a cooking field, in particular, of an induction cooking field. The cooking field device may also comprise the entire cooking field, in particular, the entire induction cooking field. Preferably, the heating unit is made as an induction heating unit, and is preferably provided to supply an alternating electromagnetic field with a frequency between 20 kHz and 100 kHz, which is intended to be transformed into heat in the base of a metal cooking battery, preferably ferromagnetic, resting on it, through induction of eddy currents and / or magnetic inversion effects. The heating conductor is an element intended to conduct electric current, in particular, alternating electric current, in at least one state of heating operation, and can generate at least a part of the alternating electromagnetic field supplied by the heating unit, and which conforms a minimum part of the current conductive heating unit and, advantageously, macroscopic. The heating conductor is preferably made as a one-piece element, and is intended to conduct an alternating electric current with a frequency between 20 kHz and 100 kHz, and to generate a power of at least 500 W, preferably 750 W 5 at least and, advantageously, at least 1,000 W. At least one partial area of the heating conductor has the approximate or exactly channel-shaped conformation, where another partial area of the heating conductor that could be made in one piece with the other partial area, could have a different conformation and, in particular , which differs from an approximate or exactly shaped conformation
    image2
    10 channel In the plane of the cross section, the heating conductor wraps to a surface that does not have material of the heating conductor. The plane of the cross section is oriented perpendicular to the longitudinal extension of the heating conductor.
    Through the embodiment according to the invention, low costs can be achieved,
    15 in particular, it is possible to achieve a simple operation by manufacturing, in particular, the winding, the heating conductor, thereby making an economical manufacturing process possible. In addition, the heating conductor can be contacted easily and / or safely. By means of the high rigidity of the heating conductor, a coil support of an economical material and / or can be used
    20 advantageously dispense completely with a coil holder, so that a high operating temperature is made possible. Likewise, the material from which the heating conductor is made can be used efficiently, since, thanks to the approximate or exactly channel-shaped conformation, it is possible to avoid the appearance of the film effect. In addition, the channel can be used to drive
    25 a cooling fluid.
    In the plane of the cross-section, the heating conductor could partially or completely present an approximate or exactly angular conformation, namely, rectangular and / or square and / or triangular and / or n-angular. However, in the plane of the cross-section, the heating conductor advantageously, partially or completely, has an approximate or exactly oval shape, for example, ellipsoidal and, preferably, in the form of a circular crown. The expression that the heating conductor has an "approximately or exactly angular and / or oval and / or circular crown-shaped conformation" includes the concept that the conformation of the heating conductor differs from an angular conformation 35 and / or oval and / or circular crown shaped with a percentage by weight and / or
    image3
    volume of 30% maximum, preferably, 20% maximum, advantageously, 10% maximum and, most advantageously, 5% maximum. In this way, an economical manufacturing process of the heating conductor can be made possible.
    5 Observed in different planes of the cross-section, the heating conductor could have different conformations along its entire longitudinal extension. In this case, the heating conductor could have, for example, the approximate or exactly channel-shaped conformation in a first plane of the cross section and, in a second plane of the cross section, an approximate or
    10 exactly in the form of "C", where the heating conductor could have interruptions, for example, in the form of grooves, along its entire longitudinal extension. However, the heating conductor is preferably made as a tube along approximately or exactly its entire longitudinal extent. The expression that the heating conductor is made as a tube at
    The length of "approximately or exactly all of its longitudinal extension" includes the concept that the heating conductor is made as a tube at least 70%, preferably, at least 80%, advantageously, at least 90% and, preferably, at least 95% of the magnitude of its longitudinal extension. The term "tube" includes the concept of a body
    20 that has a longitudinal extension and two other extensions oriented perpendicular to the longitudinal extension that have a magnitude considerably less than that of the longitudinal extension, and which could have, by way of example, a different or identical magnitude, and which define a hollow space along approximately or exactly its entire longitudinal extent, and be made as
    25 hollow cylinder with approximate or exactly circular base. In this way, a stable embodiment can be achieved, so that a coil holder of an economical material can be used and / or advantageously completely dispensed with a coil holder.
    Likewise, it is proposed that, in the plane of the cross section, the heating conductor has an inside diameter of at least 0.2 mm, preferably, at least 30 mm, advantageously, of 0.6 mm at least, more advantageously, at least 0.8 mm and, preferably, at least 1 mm. The term "inner diameter" of the heating conductor includes the concept of the diameter of the largest circle which, in the plane of the cross section, is inscribable tightly in the approximate or exactly channel-shaped conformation. Thus, you can save 35 material compared to a solid heating conductor and / or get a
    image4
    economic realization Furthermore, cooling of the heating conductor is possible, for example, by means of a cooling fluid conducted through the heating conductor.
    In addition, it is proposed that, in the plane of the cross-section, the heating conductor has a maximum internal diameter of 4 mm, preferably 3.5 mm maximum, advantageously, 3 mm maximum, so more advantageous, a maximum of 2.5 mm and, preferably, a maximum of 2 mm, which makes it easy to handle the heating conductor.
    Furthermore, it is proposed that, in the plane of the cross-section, the heating conductor has a minimum diameter of at least 1 mm, preferably at least 1.2 mm, advantageously, at least 1.4 mm, more advantageously, at least 1.6 mm and, preferably, at least 1.7 mm. The term "outer diameter" of the heating conductor includes the concept of the smaller circle which, in the plane of the cross-section, wraps tightly to the approximate or exactly shaped channel. In this way, great stability can be achieved, and the film effect can be avoided.
    It is also proposed that, in the cross-sectional plane, the heating conductor has a maximum diameter of 6 mm maximum, preferably 5 mm maximum, advantageously, 4 mm maximum, more advantageously, of 3.5 mm maximum and, preferably, 2.8 mm maximum, making it possible to achieve an economical manufacturing process.
    It is also proposed that the heating conductor be essential or completely flat. The expression that the heating conductor is "essentially or totally flat" includes the concept that two lateral edges oriented perpendicularly to each other of the smaller imaginary geometric parallelepiped that tightly wrap the heating conductor in each case have a longitudinal extension of one magnitude that is at least 5 times, preferably, at least 7 times, advantageously, at least 10 times, more advantageously, at least 15 times, preferably, at least 20 times and, more preferably, at less than 25 times the magnitude of another lateral edge of the parallelepiped that is oriented perpendicularly to both lateral edges. The vertical distance between any point of a first heating conductor surface and a cooking field plate, as well as the vertical distance between any point of a second heating conductor surface and the cooking field plate differs from the magnitude of the
    image5
    average distance of all points of the respective surface of the heating conductor with respect to the cooking field plate at a maximum of 20%, preferably, a maximum of 10%, advantageously, a maximum of 5% and , preferably, at a maximum of 3%, where the average distance is set 5 as the average value of the distances at any point on the corresponding surface of the heating conductor, where, in the installation position, the first surface is directed towards the cooking field plate and the second surface is disposed opposite to the cooking field plate, and where the first surface and the second surface form surfaces of the heating conductor facing each other, the
    10 which are oriented in the installation position approximately or exactly parallel to the main extension plane of the cooking field plate. In this way, an embodiment with which space is saved can be achieved.
    As an example, the heating conductor could be made of silver and / or gold and / or aluminum entirely or for the most part. However, the heating conductor 15 is preferably made of copper totally or for the most part. Preferably, the heating conductor does not have an insulation. The heating conductor has a maximum operating temperature of at least 150 ° C, preferably at least 200 ° C, advantageously, at least 250 ° C and, preferably, at least 300 ° C, which is limited by the melting temperature of copper, which has a value of approximately 1,085 ° C. The expression that the heating conductor is "made of copper totally or mostly" includes the concept that the heating conductor is made of copper in a percentage by weight and / or volume percentage of at least 70%, preferably, of more than 80% at least, advantageously, of more than 90%
    25 minimum and, preferably, more than 95% minimum. Thus, an economical embodiment can be achieved, as well as dispensing with an insulation of the heating conductor and making a high operating temperature possible.
    Likewise, a method is proposed for cooling a cooking field device according to the invention, with one or more heating units having at least one heating conductor that is intended to heat a cooking battery resting on it, and which has partially or completely an approximate or exactly channel-shaped conformation in at least one plane of the cross-section, where a cooling fluid is conducted through the heating conductor that is in particular a cooling liquid, and which has a conductivity electrical of 10-7 S / m 35 maximum, preferably, 10-9 S / m maximum, advantageously, 10-12
    image6
    S / m maximum and, preferably, 10-15 S / m maximum. The coolant could be, for example, distilled water. In this way, overheating can be avoided and / or a high maximum operating temperature possible.
    The induction cooking field device described is not limited to the application or to the embodiment described above, in particular being able to present a number of elements, components, and particular units that differs from the amount mentioned in the present document, as long as the purpose of fulfilling the functionality described here is pursued.
    Other advantages are taken from the following description of the drawing. Examples of embodiment of the invention are shown in the drawing. The drawing, description and claims contain numerous features in combination. The person skilled in the art will consider the characteristics advantageously also separately, and will gather them in other reasonable combinations.
    They show:
    Fig. 1 an induction cooking field with a field device of
    induction cooking, in schematic top view,
    Fig. 2 a section of a heating conductor of a unit
    heating of the induction cooking field device, in
    schematic representation,
    Fig. 3 the heating conductor, in a section representation
    schematic along line III-III of figure 2,
    Fig. 4 the heating conductor in a winding state and a battery of
    cooking supportedonhedriverfrom heating,in
    schematic representation,
    Fig. 5 the heating unit of the cooking field device by
    induction, in schematic top view,
    Fig. 6 the heating unit, in schematic rear view, and
    Fig. 7 the heating unit, a cooking field plate of the
    cooking field device, and a cooking battery supported
    above, in schematic exploded representation.
    Figure 1 shows a cooking field 20, made as an induction cooking field, with a cooking field device 10, made as an induction cooking device. The cooking field device 10 comprises a cooking field plate 22 which, in the assembled state, forms a part of an outer casing of the induction cooking field 20. The cooking field plate 22 is provided to support a cooking battery 24 (see figures 4 and 7). The cooking field device 10 comprises several heating units (see Figures 5 to 7), each of which is intended to heat the cooking battery 24 supported on the cooking field plate 22 above the heating units.
    image7
    12. In Figure 1, heating units 12 are not shown for reasons of clarity.
    The cooking field device 10 comprises a control unit 26 for entering and / or selecting operating parameters (see Figure 1), for example, the heating power and / or the density of the heating power and / or the heating zone Also, the control unit 26 is intended to give the user the value of an operating parameter.
    The cooking field device 10 comprises a control unit 28, which is intended to execute actions and / or modify settings depending on the operating parameters introduced by the control unit 26. In addition, the cooking field device 10 It comprises a power unit (not shown), which is intended to supply electric power to the electrical and / or electronic construction units.
    In an operating state, the control unit 28 assigns a heating zone to a cooking battery 24 resting on it, for which it gathers in the heating zone the heating units 12 covered by the cooking battery 24. In a state of heating operation, the control unit 28 regulates the power supply to the heating units 12, and activates the power unit so that electrical power is supplied to the heating units 12 which are in an activated state. Next, only one of the heating units 12 is described.
    The heating unit 12 has exactly one single heating conductor 14 for heating the cooking battery 24 resting on it (see Figure 2). In a plane of the cross-section, the heating conductor 14 partially presents an essentially channel-shaped conformation, which extends essentially along the entire longitudinal extension of the heating conductor 14. The heating conductor 14 defines a channel essentially along its entire longitudinal extent. In the plane of the cross section, the heating conductor 14 partially presents a conformation essentially in the form of a circular crown. The essentially channel-shaped conformation of the heating conductor 14 is made as an essentially circular crown-shaped conformation.
    image8
    The heating conductor 14 is made as a tube essentially along its entire longitudinal extension. The heating conductor 14 has an inner diameter 16 which, in the plane of the cross-section, has an essentially circular crown-shaped conformation (see Figure 3). In the plane of the cross section, the heating conductor 14 has an inner diameter 16 of approximately 1.5 mm. In addition, the heating conductor 14 has an outer diameter 18 which, in the plane of the cross-section, has an essentially circular crown-shaped conformation. In the plane of the cross section, the heating conductor 14 has an outer diameter 18 of approximately 2.3 mm.
    The inner diameter 16 and the outer diameter 18 are determined by two criteria. The first of the criteria refers to a plane of the cross-section of the heating conductor 14, which corresponds roughly to a plane of the cross-section of the entire stranded filaments of a heating conductor of a comparable heating unit . The second of the criteria refers to the efficiency of the heating conductor 14. The inner diameter 16 and the outer diameter 18 are provided together to ensure that the efficiency of the heating conductor 14 is high and / or that the loss of power of the conductor heating 14 is low. For this, the inner diameter 16 and the outer diameter 18 are determined by the calculation of finite elements, in which the power and / or the heating frequency and / or properties of the placed cooking battery are taken into account.
    In a winding state, the heating conductor 14 is spirally wound (see Figure 4), the adjacent turns of the heating conductor 14 are arranged spaced apart from each other, and the heating conductor 14 is made essentially flat. In the installation position, the heating conductor 14 is arranged under the cooking field plate 22. In the wound state, the heating conductor 14 has a main extension plane which, in the installation position, is essentially oriented parallel to the main extension plane of the cooking field plate 22.
    The main extension plane of a construction unit is parallel to the larger lateral surface of the smaller geometric parallelepiped that completely fits the construction unit, and runs through the central point of the parallelepiped.
    image9
    Much of a surface of the heating conductor 14 directed towards the cooking field plate 22 in the installation position and in the winding state defines a foreground. In the installation position, the foreground is oriented essentially parallel to the main extension plane of the cooking field plate 22. Much of a surface of the heating conductor 14 opposite the cooking field plate 22 in the position of installation and in the winding state it defines a background. In the installation position, the second plane is oriented essentially parallel to the main extension plane of the cooking field plate 22, and the main extension plane of the cooking field plate 22 is oriented essentially perpendicular to the direction of the force of gravity.
    In the wound state, the heating conductor 14 has a quantity of at least 10, preferably, at least 12 and, advantageously, at least 14 turns, and at most 40, preferably, at most 30 and, advantageously, with a maximum of 25 turns. In the present embodiment, the heating conductor 14 has an amount of 13 turns.
    The heating conductor 14 is basically made of copper, in which case the heating conductor could be made, for example, of a copper alloy with at least one other material. In the present embodiment, the heating conductor 14 is made of pure copper. The heating conductor 14 does not have an insulation. The distance between turns of the heating conductor 14 arranged adjacent to each other is at least 0.1 mm, preferably at least 0.3 mm, advantageously, at least 0.5 mm, more advantageously , at least 0.7 mm, preferably, at least 1 mm and, more preferably, at least 1.5 mm. The distance between adjacent turns is configured as the distance between the nearest and directed surfaces of the turns arranged adjacent to each other of the heating conductor 14. In the winding state, the distance defines an extension of a free space between turns arranged adjacent to each other. The distance is oriented essentially parallel to the main extension plane of the heating conductor 14, and essentially perpendicular to one or more of the surfaces of one of the turns arranged adjacent to each other of the heating conductor 14.
    As an example, a coil support could be dispensed with, which could have at least one arrangement section for the heating conductor (see Figure 4). In this case, the heating unit could have a plate on which it could be


    arranged the heating conductor in the assembled state. The plate could be made of a material that does not conduct the electric current and has a melting temperature of at least 250 ° C, preferably at least 300 ° C, advantageously, at least 350 ° and, advantageously, of 400º C minimum. The plaque could be made, for example, of mica.
    In the present exemplary embodiment, the heating unit 12 has a coil support 30 (see Figures 5 to 7). In the assembled state, the heating conductor 14 is arranged on the coil support 30, which has at least one arrangement section 32 that defines the position of the heating conductor 14 on the coil support 30. The coil support 30 It is made of electrically insulating material. In the installation position, the coil support 30 is provided to form an insulation between the heating conductor 14 and another or other construction units of the cooking field device 10.
    As an example, the arrangement section could be made in sections, where the arrangement section could have several partial sections that could jointly define the position of the heating conductor on the coil support. In this case, the arrangement section could be arranged in the partially or completely assembled state in the free space between adjacent turns of the heating conductor. In the present exemplary embodiment, the arrangement section 32 is carried out continuously and spirally. In the assembled state, the arrangement section 32 is arranged largely in a free space between adjacent turns of the heating conductor 14.
    The heating unit 12 has at least one ferrite element 34 (see Figures 5 to 7). In the present exemplary embodiment, the heating unit 12 has fifteen ferrite elements 34, although only one of the ferrite elements 34 is described below. In the assembled state, the ferrite element 34 is arranged, in particular, fixed , next to the coil support 30, which has at least one fixing section that is intended to fix the ferrite element 34 to the coil support 30.
    The heating unit 12 has at least one insulating element 36 (see Figure 7), which is made as a plate. In the installation position, the insulating element 36 is disposed between the heating conductor 14 and the cooking field plate 22. The insulating element 36 is made of an electrically insulating material. By way of example, the insulating element 36 could be made of mica.


    The cooking field device 10 comprises a refrigeration unit 38 (see Figure 4), which is intended to cool the heating conductor 14 in a heating operating state, and has at least one fluid reservoir (not shown). ) to store a refrigerant fluid. By way of example, the refrigeration unit could have a first fluid reservoir for storing unused coolant and a second fluid reservoir for storing used coolant. The refrigeration unit 38 has at least one transport element 40, which is intended to transport the refrigerant fluid from the fluid reservoir, in particular, from the first fluid reservoir, through the channel defined by the conductor of
    10 heating 14. By way of example, the transport element 40 could be made as a pump. In a process for cooling the cooking field device 10, a cooling fluid is conducted through the heating conductor 14.
    The refrigerant fluid does not conduct the electric current and is a liquid, in the present embodiment, distilled water. The refrigeration unit could, for example, have a thermal element for cooling the cooling fluid. The thermal element is intended to cool the unused refrigerant fluid. In this case, the thermal element could be provided by way of example to cool the fluid reservoir in which the cooling fluid could be found before being transported through the channel defined by the heating conductor. Additionally, the transport element 40 is provided
    20 to cool the used refrigerant fluid.
    image10
    Reference symbols
    10 Induction cooking field device
    12 Heating unit
    14 Heating conductor
    16 Inside diameter
    18 External diameter
    twenty Induction cooking range
    22 Cooking Field Plate
    24 Cooking battery
    26 Control unit
    28 Control unit
    30 Coil holder
    32 Layout Section
    3. 4 Ferrite element
    36 Insulating element
    38 Cooling unit
    40 Transport element
    权利要求:
    Claims (9)
    [1]
    image 1
    1. Induction cooking device with one or more heating units (12) having at least one heating conductor (14) that is intended to heat a cooking battery (24) resting on it,
    5 characterized in that, in at least one plane of the cross-section, the heating conductor (14) partially or completely presents an approximate or exactly shaped channel.
    [2]
    2. Cooking field device according to claim 1, characterized in that,
    10 in the plane of the cross-section, the heating conductor (14) partially or completely presents an approximate or exactly shaped circular crown shape.
    [3]
    3. Cooking field device according to claims 1 or 2, characterized
    15 because the heating conductor (14) is made as a tube along approximately or exactly its entire longitudinal extension.
    [4]
    4. Cooking field device according to one of the preceding claims, characterized in that, in the plane of the cross section, the
    20 heating conductor (14) has an inside diameter (16) of at least 0.2 mm.
    [5]
    5. Cooking field device according to one of the preceding claims, characterized in that, in the plane of the cross section, the
    The heating conductor (14) has an inside diameter (16) of a maximum of 4 mm.
    [6]
    6. Cooking field device according to one of the preceding claims, characterized in that, in the plane of the cross section, the
    30 heating conductor (14) has an outer diameter (18) of at least 1 mm.
    [7]
    7. Cooking field device according to one of the preceding claims, characterized in that, in the plane of the cross section, the
    14
    image2
    heating conductor (14) has an outer diameter (18) of a maximum of 6 mm.
    [8]
    8. Cooking field device according to one of the stated claims
    5 above, characterized in that the heating conductor (14) is made of copper totally or for the most part.
    [9]
    9. Cooking field, in particular induction cooking field, with a
    cooking field device (10) according to one of the preceding claims 10.
    fifteen
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    同族专利:
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    EP3030044A1|2016-06-08|
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    ES2573125B1|2017-03-24|
    引用文献:
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    FR2972890B1|2011-03-18|2014-07-25|Inst Polytechnique Grenoble|INDUCTIVE SYSTEM THAT CAN SERVE COLD CUP|
    JP2013161767A|2012-02-09|2013-08-19|Kansai Electric Power Co Inc:The|Ih-type heating cooker|
    CN203136222U|2012-12-31|2013-08-14|江苏康尔臭氧有限公司|High-frequency induction heating coil in inner electrode tube bottom blank forming device|EP3432687B1|2017-07-20|2020-03-04|Vestel Elektronik Sanayi ve Ticaret A.S.|Cooker and method of cooling|
    CN110611969B|2019-09-12|2021-10-26|北京动力机械研究所|Induction coil cooling and pressure-bearing system of induction heating equipment|
    法律状态:
    2015-06-05| PC2A| Transfer of patent|Owner name: BSH HAUSGERATE GMBH Effective date: 20150529 |
    优先权:
    申请号 | 申请日 | 专利标题
    ES201431794A|ES2573125B1|2014-12-04|2014-12-04|Induction cooking device with heating unit|ES201431794A| ES2573125B1|2014-12-04|2014-12-04|Induction cooking device with heating unit|
    EP15196016.8A| EP3030044B1|2014-12-04|2015-11-24|Hotplate device|
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