• 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 an intelligent roasting thermometer comprising the possibility of measuring temperature at three or more places in the meat, if at least one is measured on the other side of the core of the meat opposite the insertion point, so that the core is between two measurements after insertion, the seed temperature can be estimated, and wherein the roasting thermometer is additionally designed to be inexpensive to manufacture as well as may include an external unit for calculating, e.g. via wireless connection, measurement data received as well as display of these calculations and setting parameters for use in the calculations.
    公开号:DK201800226A1
    申请号:DKP201800226
    申请日:2018-05-22
    公开日:2019-03-20
    发明作者:Kristensen Kasper;Kloster Martin
    申请人:Cookperfect Aps;
    IPC主号:
    专利说明:

    Intelligent roasting thermometer
    The invention relates to an intelligent roasting thermometer adapted to measure the temperature at three or more separate locations in meat using at least one temperature sensor for each location, thereby being able to estimate the core temperature of the meat.
    The invention relates to an intelligent roasting thermometer adapted to measure the temperature at three or more separate locations in meat. It comprises a probe with at least three sensors, the probe being a stainless steel tube and the sensors located longitudinally on the inside of the steel tube.
    If at least one temperature is measured on the other side of the core of the meat opposite the insertion point, so that the core is between two measurements, the roasting thermometer will be able to estimate the core temperature of the meat.
    The measured temperatures are sent to an external device for display on a screen or external device either by cable or wireless.
    The internal or external unit is arranged to make a calculation of the measured measurement data as well as display of e.g. the core temperature possibly as a function of time and can also be arranged for setting parameters for use in the calculations, so that any residual rise time can be estimated.
    Prior art in the art comprises DE102012222151 A1, which describes a method for the operation of a roasting thermometer with at least three sensors on an elongated probe. The at least three measurement values from the at least three sensors are used for interpolation between the measurement values to find a minimum value which is the core temperature. The document states that even smallest order polynomials can be found, so-called Larange polynomials, from which the minimum temperature can be estimated. In addition, it is stated that Newtonian algorithms can also be used.
    DK 2018 00226 A1
    The probe is described in that it may be a steel tube within which the sensors may be distributed equally longitudinally. In FIG. 1 in the document, a conductor from the sensors is shown back to the top of the probe.
    Another roasting thermometer is described in WO2006035005 and DE102004047756. The probe consists of a small diameter stainless steel tube selected to reduce the heat conduction along the probe walls. Inside the probe are a number of sensors and for each sensor an energy saving unit made of quartz to collect vibrational energy.
    Ensuring the correct core temperature of the meat is absolutely essential for the culinary quality and hygiene, and experiments have shown that, as little as one centimeter from the center of the meat can be up to 10 ° C higher when frying at higher oven temperature than 160 ° C. In addition, it has been shown by experiments that the variation in the preparation of the core temperatures of the meat is generally very large (> 20 ° C), resulting in very different culinary quality. Another problem is that the meat fades the higher the core temperature becomes. Finally, if the core temperature is too low, it may be a hygienic problem.
    Therefore, it will be optimal to be able to estimate the core temperature as well as possible without incurring excessive costs for the production of the probe for measuring the core temperature.
    The object of the present invention is thus to provide an intelligent roasting thermometer which estimates the core temperature with as much accuracy as roasting thermometers according to the prior art, but which is simultaneously inexpensive to manufacture.
    DK 2018 00226 A1
    Brief Description of the Invention
    The object of the invention is met by an intelligent roasting thermometer of the type specified in the preamble of claim 1, characterized in that the probe comprises a tube or the like of a stainless steel heat-conducting material such as steel material having a thickness of between 0.05 mm and 0. 30, preferably between 0.05 mm and 0.25 mm, most preferably 0.25 mm, and that the probe is further arranged with a distance between the sensors (5) in the steel pipe of less than 15 mm, preferably at least 10 mm at a thickness of 0.05 mm, and at a distance of between 15 mm and 20 mm at a thickness of between 0.05 mm and 0.25 mm, and at a distance of more than 20 mm at a thickness of 0,25 mm or more.
    Suitable embodiments of the invention are set forth in claims 2 to
    7th
    The invention will now be explained in more detail with reference to the drawings, in which:
    FIG. 1 shows a thermometer according to the invention.
    FIG. 2 shows insertion of a roasting thermometer, while
    FIG. 3 is a cross-sectional view of a roasting thermometer according to the invention, while FIG. 4 shows a screenshot of a roasting control app using roasting thermometer according to the invention, while
    FIG. 5 and 6 show other screenshots of the App according to the invention.
    The abbreviation App is for an application loaded on a smartphone (modern mobile phone) or tablet.
    Figures 1, 2 and 3 show an example of a roasting thermometer according to the invention for measuring temperatures in a piece of meat. It comprises a probe (1) for insertion into
    DK 2018 00226 A1 one piece of meat (2). a handle (3) made of a heat insulating material and connected by wire (15) or wirelessly (not shown) to a device adapted to receive collected measurement data, calculate, set and display settings and measurement results, whether or not they are calculated or directly read.
    The roasting thermometer probe (1) is intended for inserts above the middle of meat (2) that are roasted or roasted on a grill, in an oven or roasting pan or otherwise heat-treated. The probe (1) is made as a tube which is tapered and reinforced at the end (16, Fig. 2) to be inserted into the meat (2). The tube (1) is formed of a thin-walled stainless steel material (see Fig. 3) to obtain the least possible heat conduction, while at the same time ensuring a reasonably reliable temperature measurement at the sensors (5 and 14) inserted at regular intervals (4). the steel pipe (1).
    The probe (1) of the roasting thermometer could also include a wireless communication transmitter (not shown) with a proprietary external device or an App on an external device, be it a smartphone or tablet or other capable of receiving, process and display processed and measured data, etc.
    The device can be a proprietary part of the thermometer or an App installed on a smartphone, tablet etc. or similar for real temperature display, calculate and display core temperature, show estimated residual rise time (8) calculated from measured or calculated core temperature data (7), and heat gradient that can be measured, calculated or set as an empirically determined size which only depends on the nature and age of the meat.
    The probe (1) on a roasting thermometer according to the invention is provided with a number of at least 3, but preferably 4 or more, sensors (5,14), at least 3 of which are intended to measure the temperature inside the meat (2). The sensors (5) may advantageously be of the types of thermistor or thermocouple. The sensors (5) are in direct contact with the inside of the steel tube of the probe (1) to obtain the best and most reliable measurement at each sensor (5, 14).
    DK 2018 00226 A1
    The example of the step thermometer in FIG. 1 has a probe (1) containing five sensors (5 and 14), one (14), A, for measuring the temperature outside the meat (2), and four (5), B, C, D and E, for measuring of temperatures fling places through the flesh.
    It has been experimentally shown that by measuring at least 3 but preferably several separate points in a fixed piece of meat (2) and where at least one of these points is on the other side of the core of the meat (2) relative to the insertion point (see Fig. 1) is possible to derive a temperature curve through the meat (2) from which the coldest point in the meat (2), the core temperature, is estimated, thereby allowing the roasting thermometer to be placed easily and conveniently, and the desired result is ensured each time .
    Roasting thermometer is at the same time inexpensive to manufacture. It has been found that it is important to use, for example, a stainless steel tube (1) with as small a thickness as possible, so that the heat conduction resistance is as high as possible. The reason is that heat conduction from the thermally conductive material at a neighboring sensor causes an error display due to transferred heat from another location in the meat via heating of the probe (1) tube. Therefore, a thin thickness of goods will mean that the temperature of the meat around the sensor in question is measured only with no or only a minimal error indication.
    At a thickness of the stainless steel tube of 0.25 mm, tests have shown that a distance between the sensors (5) of 20 mm or more reduces the heat influence of the sensors (5) from the surrounding heat source to a minimum level that can be neglected, at the same time as that the control of the roasting temperature of the meat (2) is still quite accurate.
    If you want to go further into the thickness of the probe (1), so that the heat conduction resistance is increased even more, great demands are made on
    DK 2018 00226 A1 manufacturing process of the probe (1), where 0.25 mm has proved to be a good compromise.
    However, tests have shown that at a good thickness of 0.05 mm, the distance of the sensors (5) can be reduced to less than 15 mm, where the precision and measurement accuracy are still quite accurate. If the distance is less than 10 mm, the measurement accuracy becomes poor.
    When the tube of the probe is arranged with the specified thicknesses and associated distances between the sensors (5), the probe (1) can be manufactured very cheaply, because no other detailed manufacturing process is required. At the same time, the probe (1) can be used to estimate the core temperature with high precision.
    The estimation can be done by advantageously using the measurement data obtained from the temperature measurements as set out in claim 2 to set up a temperature curve and from this derive the minimum temperature, which is the core temperature of the meat, using a Lagrange polynomial or Newtonian algorithms.
    In this way, it thus becomes possible to estimate the core temperature of the meat very precisely, thereby largely avoiding the disadvantages of insufficient precision of an estimated core temperature.
    Studies have shown that using Lagrange polynomial compared to other algorithms is optimal for calculating the meat's core temperature from this temperature curve and thus calculating it very accurately. As mentioned, however, at least one measuring point must be located past the center of the meat (2).
    DK 2018 00226 A1
    With the design of the roasting thermometer as disclosed by this invention, a user will have no doubt whether he has hit the center of the meat and thus has been able to obtain an even very accurate core temperature measurement, thus providing the basis for achieving maximum culinary quality with reasonable security.
    When preparing a piece of meat, the meat is placed on a heat source (directly or indirectly) so that the surrounding heat heats the cold piece of meat until it has reached the desired roasting temperature, after which the meat is removed from the heat source.
    As set forth in claim 3, the roasting thermometer may comprise an external computing device which is an App for use on smartphones or tablets and the like. or another similar device capable of receiving input and calculating and displaying results from these. If this is achieved, the advantage of integrating the mathematical calculations of the core temperature and rise time in the App causes the processing power of smartphones and tablets to be utilized, which significantly reduces the cost of manufacturing the thermometer electronics.
    Other suitable embodiments of the invention are set forth in claims 4 to 7.
    Other advantages of the present invention include:
    For long-term roasting, you want to retain all the juice, power and taste in the meat. This is done by keeping the oven / grill temperature at low heat.
    To ensure optimal long-term roasting, the temperature difference between the core temperature and the surface of the meat should be as small as possible.
    A useful technology must be able to measure the core temperature as well as the temperature difference through the meat, thus ensuring the correct long-term roasting.
    DK 2018 00226 A1
    Said invention solves this problem, since the temperature difference through the meat is measured from the ambient temperature, as in the example of FIG. 1 is A, (14) which is in an oven the oven temperature, and measurement data on temperatures from the sensors (5) B, C, D and E. The temperature difference when cooking in an oven can be adjusted to the desired level by adjusting the oven temperature.
    Another advantage of the invention is that calculation of the rise time is possible. When the core temperature of the meat is known, it is possible to calculate the remaining roasting time until the desired core temperature is obtained at the ambient temperature concerned. It is also possible to show what ambient temperature the oven or grill should be set at a predetermined cooking time.
    Especially when grilling, experiments have shown that the accuracy of the calculated roasting time depends on the elapsed time. At the beginning of the grilling process, the calculated cooking time is very inaccurate, but after approx. 5-8 minutes it is possible within a few minutes to calculate when the cooking is completed. Calculating the rise time becomes more and more accurate as time goes on. The calculation of the rise time takes place continuously, so that changes in the ambient temperature are taken into account.
    Figure 4. shows an example of a wireless device that can communicate with the intelligent roasting thermometer. Here is an App installed on a smartphone or tablet. The principle can easily be transferred to any device capable of communicating, wirelessly or not, with the roasting thermometer, and thereby capable of receiving measurement data, calculating, setting and displaying settings and measurement results, whether calculated or not. directly read, The FIG. 4 to FIG. The App shown in Fig. 6 is provided with means for visualizing core temperatures (7), rise time (8) and alarms throughout the roasting process.
    DK 2018 00226 A1
    The unit shown is designed for ease of use and, in addition to the means for visualizing core temperatures (7), etc., also includes means for setting alarms (9) and not least includes means for setting the setting of the frying process. For example, the App is equipped with several options for selecting frying parameters, mainly core temperature. They can include is reached by those in FIG. 5, you can manually select the frying process. Here, a setting of a roasting temperature can be made at Meat temp, which is a manual setting of the desired core temperature, but the roasting process can also be selected by choosing between displayed Visual images of meat prepared at different temperatures (see fig. 6). Using the slider (13), you can switch between the 5 general types of cooking that are when preparing a piece of beef: the categories - Rare, Medium Rare, Medium, Medium Done and Well Done.
    By simply browsing between these categories, the App displays images of the current category, so that on the basis of a visual impression, the desired result is decided upon selection, whereby the App sets the necessary parameters and at the same time displays pictures of it. current category.
    Said invention may also conceivably be integrated with the control of an oven or burner (grill) so that desired parameters can be controlled throughout the cooking time without manually controlling the heat or cooking time. This may be possible. be automatic regulation of an oven or burner (grill) to obtain the meat preparation defined by core temperature, roasting time and temperature difference through the meat, primarily by long-term roasting.
    权利要求:
    Claims (7)
    [1]
    An intelligent roasting thermometer comprising a probe (1) having at least three temperature sensors (5) for temperature measurement at least three places in the meat (2), at least one of the temperature sensor (5) after insertion into the meat is on another side of the core of the meat opposite to the insertion location, so that the core is adjacent to a location between the two temperature sensors (5), whereby the core temperature of the meat can be estimated, and which further comprises a unit for calculating, e.g. via wireless connection, measurement data received and presentation of the results of these calculations such as residual step time (8) and for setting parameters for use in the calculations, characterized in that the probe (1) comprises a tube of a stainless steel conductive material such as steel, where thermal conductive material has a thickness of between 0.05 mm and 0.30 mm, preferably between 0.05 mm and 0.25 mm and most preferably 0.25 mm, and in that the probe (1) is further arranged at a distance between the temperature sensors (5) in the steel pipe of less than 15 mm preferably at least 10 mm at a thickness of up to 0.05 mm and with a distance of between 15 mm and 20 mm at a thickness of between 0.05 mm and 0.25 mm and at a distance of more than 20 mm at a thickness of 0.25 mm or more.
    [2]
    An intelligent step thermometer according to claim 1, wherein the calculation is performed using a Lagrange polynomial or Newtonian algorithm.
    [3]
    Intelligent roasting thermometer according to claims 1 and 2, characterized in that the unit is an external unit for calculation e.g. an App for
    GB 2018 00226 A1 application on smartphones or tablets and the like. or any other equivalent external device capable of receiving input on the sensors' measurement data and making calculations and displaying results from them.
    [4]
    Intelligent roasting thermometer according to claims 1 to 3, characterized in that the probe (1) comprises a transmitter for wireless transmission of measurement data.
    [5]
    Intelligent roasting thermometer according to claims 1 to 4, characterized in that the measurement data and calculations obtained from the temperature measurements are further used for calculating roasting time, based on calculation of the development in the core temperature.
    [6]
    Intelligent roasting thermometer according to claims 1 to 5, characterized in that the mathematical calculations of core temperature and roasting time are integrated in the App.
    [7]
    Intelligent roasting thermometer (1) according to claims 1 to 6, characterized in that the App comprises the possibility of visually adjusting the desired roasting temperature.
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    同族专利:
    公开号 | 公开日
    EP3682206A1|2020-07-22|
    CA3073468A1|2019-03-21|
    DK179682B1|2019-03-20|
    EP3682206A4|2021-06-09|
    US20210010870A1|2021-01-14|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE102004047756B4|2004-09-30|2012-03-01|BSH Bosch und Siemens Hausgeräte GmbH|Temperature sensor device|
    US20140341254A1|2013-05-14|2014-11-20|W.C. Bradley Co.|Cold spot meat probe|
    法律状态:
    2019-03-20| PAT| Application published|Effective date: 20190313 |
    2019-03-20| PME| Patent granted|Effective date: 20190320 |
    优先权:
    申请号 | 申请日 | 专利标题
    DKPA201770680|2017-09-12|
    DKPA201770680|2017-09-12|PCT/DK2018/050208| WO2019052613A1|2017-09-12|2018-08-27|Intelligent meat thermometer|
    EP18855320.0A| EP3682206A4|2017-09-12|2018-08-27|Intelligent meat thermometer|
    US16/646,856| US20210010870A1|2017-09-12|2018-08-27|Intelligent meat thermometer|
    CA3073468A| CA3073468A1|2017-09-12|2018-08-27|Intelligent meat thermometer|
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