• 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:
    Gas cooking appliance comprising at least one gas burner (10), at least one gas electromagnetic valve (20) fluidically communicating the gas of a gas line (30) with the burner (10), one gas unit control (40) controlling the electromagnetic valve (20), at least one temperature sensor (50) electrically connected to the control unit (40) for measuring a temperature of a container (70) arranged in the burner (10), and capacitive sensing means (60) of the container (70) comprising at least one electrode electrically connected to the control unit (40), the capacitive sensing means (60) being disposed next to the burner (10). The capacitive sensing means (60) comprises the temperature sensor (50) which acts as the electrode of the capacitive sensing means (60), and insulation means (90) electrically insulating the temperature sensor (50) of the burner (10). (Machine-translation by Google Translate, not legally binding)
    公开号:ES2695776A1
    申请号:ES201730888
    申请日:2017-07-04
    公开日:2019-01-10
    发明作者:Andueza Félix Querejeta;Bayon Aitor Zabalo
    申请人:Copreci S Coop;
    IPC主号:
    专利说明:

    [0001]
    [0002] Gas cooking appliance
    [0003]
    [0004] TECHNICAL SECTOR
    [0005]
    [0006] The present invention relates to gas cooking appliances.
    [0007]
    [0008] PRIOR STATE OF THE TECHNIQUE
    [0009]
    [0010] Gas cooking appliances are known which comprise at least one gas burner fed with a gas flow regulated by an electromagnetic gas regulation valve. These gas cooking apparatuses also generally comprise at least one temperature sensor arranged in the gas burner which measures the temperature of a container arranged in the burner, and a control unit that controls the electromagnetic valve. The temperature sensor is usually electrically connected to the control unit, so that the control unit, as a function of the temperatures measured by the temperature sensor, controls the electromagnetic valve.
    [0011]
    [0012] Also known are cooking apparatuses comprising at least one heat source, a control unit, and capacitive detection means that allow detecting the presence of a container in the heat source. These capacitive detection means are arranged close to or in the heat source, and comprise at least one electrode electrically connected to the control unit, so that the electric field generated by the electrode is interrupted by the container when it is disposed in the focus of heat, the control unit determining the presence of said container.
    [0013]
    [0014] JP2014190559A discloses a gas cooking appliance comprising three gas burners, a gas electromagnetic valve for each burner that fluidically communicates the gas coming from a gas conduit with the burner, a control unit that controls the electromagnetic valve, a sensor of temperature per connected burner electrically to the control unit for measuring a temperature of a cooking vessel disposed in the burner, and capacitive detection means of the vessel, comprising four electrodes electrically connected to the control unit, the capacitive detection means being arranged next to the burner .
    [0015]
    [0016] EXHIBITION OF THE INVENTION
    [0017]
    [0018] The object of the invention is to provide a gas cooking apparatus, as defined in the claims.
    [0019]
    [0020] The gas cooking appliance of the invention comprises at least one gas burner, at least one gas electromagnetic valve that fluidically communicates gas from a gas line to the burner, a control unit that controls the electromagnetic valve, less a temperature sensor electrically connected to the control unit for measuring a temperature of a cooking vessel disposed in the burner, and capacitive detection means of the container comprising at least one electrode electrically connected to the control unit, the Capacitive detection means next to the burner.
    [0021]
    [0022] The capacitive detection means comprises the temperature sensor, said temperature sensor acting as the electrode of the capacitive detection means, and insulating means electrically insulating the temperature sensor of the burner.
    [0023]
    [0024] The gas cooking appliance of the invention integrates the temperature sensor in the capacitive detection means as an electrode, also integrating insulation means between the temperature sensor and its immediate environment, so that a capacitor is electrically isolated from its environment, in particular electrically isolated from the burner next to which the temperature sensor is arranged, so that an electric field is produced between the temperature sensor and a metal part different from the burner. Thus, the measurement of the temperature of a container disposed in the gas burner and the detection of the presence of said temperature are obtained with the same means. container in the burner, reducing the number of components needed to perform these functions, and the cost.
    [0025]
    [0026] These and other advantages and characteristics of the invention will become apparent in view of the figures and the detailed description of the invention.
    [0027]
    [0028] DESCRIPTION OF THE DRAWINGS
    [0029]
    [0030] Figure 1 shows a general outline of a realization of a gas cooking appliance according to the invention, with an ignited and flameless gas burner and capacitive detection means, with a cooking vessel remote from the burner.
    [0031]
    [0032] Figure 2 shows the gas cooking apparatus of Figure 1, with the gas burner lit and with flame, and the cooking vessel disposed in the burner.
    [0033]
    [0034] Figure 3 shows a partial front view in detail of the gas burner, ignited and with flame, and of the capacitive detection means of the embodiment of Figure 1, with a cooking vessel disposed on the burner.
    [0035]
    [0036] Figure 4 shows a partial perspective view of the gas burner, the support grill of the cooking vessel, and the capacitive detection means shown in Figure 3.
    [0037]
    [0038] Figure 5 shows a partial detailed front view of the gas burner and the capacitive detection means shown in Figure 3.
    [0039]
    [0040] DETAILED EXHIBITION OF THE INVENTION
    [0041]
    [0042] The embodiment of the gas cooking appliance 200 of the invention shown in Figures 1 and 2, comprises at least one gas burner 10 in which a container 70 is disposed. The gas cooking appliance 200 also comprises a gas valve. 100 drive manual for said burner 10. The gas valve 100 is fluently communicated with a gas inlet conduit 30 that feeds said gas valve 100, and comprises a gas outlet connected fluently with the gas burner 10, and which allows its supply With gas. The gas valve 100 comprises a manual actuator that is adapted to act on the regulation valve 100 to regulate the flow of gas to the gas burner 10. The gas valve 100 is in this embodiment of the gas cooking appliance 200, of the type comprising a rotary regulating element disposed inside the gas valve 100, in the gas flow passing through said regulating valve 100. The regulating element communicates fluidically with the gas inlet and outlet of the gas valve 100, as a function of the angular displacement of the regulating element, within an operating range in which the supply of gas to the burner 10 occurs, when it is actuated by the manual actuator to which it is attached.
    [0043]
    [0044] The embodiment of the gas cooking appliance 200 shown comprises a pilot burner 120 which is disposed next to the gas burner 10. The regulating valve 100 supplies a gas flow to the pilot burner 120 in a constant manner. In this embodiment, the range of action in which a gas supply to the pilot burner 120 is produced, is the same range of action as the gas supply of the regulator element to the burner 10.
    [0045]
    [0046] The gas cooking appliance 200 also comprises an electromagnetic valve 20. This electromagnetic valve 20 is, in this embodiment of the gas cooking appliance 200, a normally open ON-OFF solenoid gas valve, that is, it has a duct of gas inlet, and a gas outlet conduit communicated through a gas passage, and a closure member (not shown in the figures), so that by electrical signals said closure member is either in a position OFF closing the gas passage, or in an ON position leaving the gas passage open, maintaining the electrical signal. If there is no electrical power the closing member passes and is always kept in the ON position with the gas passage open. This allows that if the gas cooking appliance 200 runs out of electrical power, said apparatus can be manually operated by acting on the regulating valve 100. Other types of electromagnetic valves 20 can also be used, such as for example a solenoid type valve normally closed, or a bistable type valve whose closing member passes from the ON to OFF position or the Reverse by electrical pulses, without the need to maintain the electrical signal. The electromagnetic valve 20 is disposed between the regulation valve 100 and the gas burner 10, allowing its fluid communication.
    [0047]
    [0048] The gas cooking appliance 200 comprises a control unit 40, said control unit 40 electrically controlling the electromagnetic valve 20, sending electrical signals to pass said valve from the ON position to OFF and maintain it. And also the gas cooking appliance 200 comprises a temperature sensor 50 configured to be arranged in contact with the container 70, in particular in contact with the bottom 71 of the container 70, when the container 70 is arranged in the burner 10, and measuring the temperature of said container 70. The temperature sensor 50 is electrically connected to the control unit 40, so that said sensor sends electrical signals to the control unit 40 associated with the temperatures that are being captured in the container 70. during the cooking process established. This temperature sensor 50 can be of different types, usually being thermistors, either PTC or NTC.
    [0049]
    [0050] In the gas cooking appliance 200 shown in this embodiment, when the control unit 40 sends a closing electrical signal to the OFF position to the electromagnetic valve 20, there is no gas flow from the regulating valve 100 to the burner 10. of gas, and in this way it is achieved that the burner 10 is without flame. For the burner 10 to turn on again when the control unit 40 stops sending the electrical signal to the electromagnetic valve 20, and this valve 20 goes to the ON position of open allowing the flow of gas to the burner 10, the apparatus of gas cooking 200 of this embodiment comprises the pilot burner 11 that the user ignites when said gas cooking appliance 200 begins to operate.
    [0051]
    [0052] The gas cooking appliance 200 also comprises a capacitive detection means 60 of the container 70. These capacitive detection means 60 comprise in this embodiment an electrode electrically connected to the control unit 40, the capacitive detection means 60 being disposed in the interior of the burner 10. These capacitive detection means 60 comprise the temperature sensor 50, said temperature sensor 50 acting as an electrode of the capacitive detection means 60, and also comprises an insulation means 90 that electrically insulates the sensor from burner temperature 50. The capacitive detection means 60 form a capacitor with a capacitance that changes with the presence of the container 70, the control unit 40 detecting said change in capacitance, and generating an electrical signal that activates the electromagnetic valve 20, passing to an open or closed gas flow position depending on the presence or absence of the vessel 70.
    [0053]
    [0054] Figure 3 shows a partial front sectional view in detail of the burner 10 of ignited and flamed gas, and of the capacitive detection means 60 of the embodiment of Figure 1, with the cooking vessel 70 disposed on the burner 10. Figure 4 shows a partial perspective view of the gas burner 10, the grate 80 for supporting the cooking vessel 70, and the capacitive detecting means 60. Figure 5 shows a partially detailed front sectional view of the burner 10. of gas and capacitive detection means 60.
    [0055]
    [0056] The temperature sensor 50, in this embodiment of the gas cooking appliance 200, has a substantially cylindrical shape and comprises an outer casing 51 constructed of electrical conductive material and of low thermal resistance, so that it can act as an electrode of the media capacitive detection 60, and at the same time having low thermal resistance or high thermal conductivity, can transmit the temperature of the bottom 71 of the container 70. The housing 51 of the temperature sensor 50 is electrically connected to the control unit 40 by a wire 52 of electrical connection. The control unit 40 has a connection to an external power source and further comprises an alternative energy source to the external power source, which is a battery (not shown in the figures). In this way, the control unit 40 when activated energises the electrode of the capacitive detection means, that is, it puts the housing 51 of the temperature sensor 50 in tension. Thus, an electric field EF is generated between the housing 51 and a metal part 80 of the gas cooking appliance 200, in this embodiment the metal part 80 being a grill arranged around the burner 10, grill in which the container 70 rests when it is to be cooked.
    [0057]
    [0058] In order for the capacitive detection means 60 to perform their detection function, it is necessary that they comprise the isolation means 90, so that the electrode, that is the housing 51, is electrically isolated and has no electrical interference. When configuring the capacitive detection means 60 a capacitor, said capacitor has a capacitance whose value is measured by the control unit 40. When the container 70 is remote from the burner 10 and the capacitive detection means 60 are activated, the electric field EF between the housing 51 and grill 80, producing a micro electric conduction between both parts. If the housing 51 is well insulated electrically said electrical conduction will not suffer changes, and the capacitance of the capacitor will have a determined value.
    [0059]
    [0060] When the container 70 is disposed in the burner 10 resting on the grate 80, the electric field EF is altered by the interposition of the container 70, causing an alteration of the electrical conduction between the housing 51 and the grate 80, so that the capacitance of the capacitor configured by the capacitive detection means changes its value, the change in value of the capacitance being determined by the control unit 40. The control unit 40 could, with this change in the value of the capacitance, send an electrical signal to the electromagnetic valve 20 to open the gas passage, the gas flow reaching the burner 10, producing the ignition of a flame 14 with the help of the flame of the pilot burner 11, as shown in Figure 2.
    [0061]
    [0062] Next to the housing 51 of the temperature sensor 50 is the burner 10, which is normally metal. So that there are no electrical branches from the housing 51 towards the burner 10, the insulation means 90 are arranged. These insulation means 90 are in this embodiment of ceramic material resistant to high temperatures, of approximately 1000 ° C, since they are the temperatures that occur in the vicinity of the gas burner 10. The insulation means 90 surrounds the housing 51, one end of the housing 51 protrudes from said insulation means 90, and protrudes from the support plane for the container 70, which defines the upper part of the grate 80. Thus, in this embodiment of the gas cooking appliance 200, when the container 70 is placed in the burner 10 on the grill 80, the bottom 71 of the container moves down the housing 51, the contact maintaining the upper part of the housing 51 and the bottom 71
    [0063]
    [0064] The burner 10 has in this embodiment of the gas cooking appliance 200 a substantially cylindrical shape, comprising a burner body 11 which is covered on its upper part with a burner cap 12, and a burner base 13 on which the burner body 11 is supported. Both the burner body 11, the burner cap 12 and the burner base 13 have a hollow interior space. The hollow interior space of the burner body 11 and the burner cap 12 is occupied in a tight manner by the insulation means 90, which are therefore arranged between the burner 10 and the temperature sensor 50, the housing 51 of the temperature sensor 50 centered with respect to the burner 10 and the surrounding insulation means 90. The burner base 13 comprises a gas and air inlet 15 which fluidically connects to the gas flow outlet of the electromagnetic valve 20. The gas inlet 15 communicates inside the burner base 13 with a gas conduit, which is fluidically connected with the burner body 11. The burner body 11 comprises a plurality of outlets of the gas and air flow coming from the internal gas conduit, the flame 14 being produced with the flame of the pilot burner 120.
    [0065]
    [0066] The burner body 11 has a stepped interior shape at different levels. The insulating means 90 comprise a lower guide 91, with a central inner hole 92 passing through it, the lower guide 91 being supported on a step inside the burner body 11. The temperature sensor 50 is disposed inside the orifice 92, traversing it, and is coupled to the lower guide 91 as will be described later.
    [0067]
    [0068] The insulation means 90 also comprise in this embodiment an upper guide 93 with a central inner hole 94 through it. This hole 94 is aligned with the hole 92 of the lower guide 91, and both holes 92 and 94 have the same diameter. The upper guide 93 is supported on a second step inside the burner body 11, which is at a higher level with respect to the step on which the lower guide 91 rests. This upper guide 93 at the same time supports its lower face on the upper face of the lower guide 91, and supports an outer side face in said lower guide 91, and supports a second outer side face on an inner side face of the burner cap 12. In this way, the two pieces of the means of Insulation, lower guide 91 and upper guide 93 are fully adjusted in the burner 10. The temperature sensor 50 is disposed inside the holes 92 and 94, the housing 51 being slidably adjusted in the axial direction in said holes 92 and 94
    [0069]
    [0070] So that the housing 51 moves downwards when the bottom 71 of the vessel 70 in the burner 10 on the grate 80, and the contact of the upper part of the housing 51 and the bottom 71 can be maintained, the capacitive detection means 60 comprise elastic means 61 coupled to the isolation means 90 and to the sensor of temperature 50. The elastic means 61 are in this embodiment a spring. The upper guide 93 comprises a housing 95 in its interior around the hole 94, and the housing 51 of the temperature sensor 50 comprises a flap 57 on its outer surface that surrounds it. When the container 70 is not arranged in the burner 10, and the upper end of the housing 51 protrudes from the insulation means 90, the flap 57 is disposed halfway up in the housing 95. The spring 61 is disposed in a housing 96 arranged inside the lower guide 91, around the hole 92. The housing 96 and the housing 95 are communicated, so that the spring 61 protrudes from the housing 96 towards the housing 95, the fin 57 of the housing 51 being supported on the spring 61. When the bottom 71 of the container 70 is arranged in the burner 10, resting on the upper end of the housing 51 of the temperature sensor 50, the housing 51 retracts downwards along the holes 92 and 94, and compressing in this way the spring 61. Said spring 61 is compressed, maintaining tension, and maintains contact between the bottom 71 of the container 70 and the housing 51 of the temperature sensor 50.
    [0071]
    [0072] The temperature sensor 50 comprises inside the housing 51 a resistive sensor 53, which is a temperature sensor based on the variation of the resistance of a conductor with the temperature. The resistive sensor 53 is connected to the control unit 40 by two electrical connection wires 55, 56. The temperature sensor 50 also comprises a sealant 54 which is disposed inside the housing 51, between said housing 51 and the resistive sensor 53. The sealant 54 is made with an electrical insulating material, so as not to derive the electrical conduction in the housing 51, and in turn the material is not thermal insulation, but allows thermal conduction. The resistive sensor 53 captures the temperature of the bottom 71 of the container 70 through the housing 51 and the sealant 54, and converts it into electrical signals, so that through the electric connection wires 55, 56 transmits said signals to the control unit 40. Thus, said control unit 40 captures the temperature of the container 70, compares it with temperatures of cooking programs memorized and put into practice, and its processor makes the opportune decisions of opening or closing the electromagnetic valve 20.
    [0073] The gas cooking appliance 200 also comprises in this embodiment a thermocouple 110 disposed next to the burner 10, and specifically next to the pilot burner 120, said thermocouple 110 being electrically connected to an electromagnetic valve of the regulation valve 100 (not shown in FIGS. figures). This thermocouple 110 has a safety function, since due to the flame of the pilot burner 120, which is always on, the electromagnetic valve of the regulating valve 100 is open and the gas flow, when appropriate, is conducted to the valve electromagnetic 20. However, when for some reason the flame is extinguished in the pilot burner 120, the electromagnetic valve of the regulating valve 100 closes, closing the gas flow to the electromagnetic valve 20.
    [0074]
    [0075] The gas cooking apparatus 200 also comprises in this embodiment a spark igniter 130 disposed next to the burner 10. This spark igniter 130 is electrically connected to the control unit 40, and its function is alternative to the function of the pilot burner 120 , the control unit 40 being the one sending the ignition signals to the spark igniter 130. Each time that the electromagnetic valve 20 is closed and the burner 10 is turned off, the new ignition of said burner 10 is with the spark igniter 130.
    [0076]
    [0077] In this embodiment of the gas cooking appliance 200, the control unit 40 is activated when the manual actuator of the gas valve 100 is moved, since it activates an electric switch. The gas cooking appliance 200 also comprises a remote control unit 140, the connection between the control unit 40 and the remote control unit 140 being activated when the manual actuator is moved axially. The remote control unit 140 allows to monitor and control the gas cooking appliance 200, which can be the connection with the wireless or wireless control unit 40. The remote control unit 140 can be a smart mobile phone or a tablet.
    [0078]
    [0079] The control unit 40 preferably comprises visual and acoustic alarm means, said alarm means alerting the user when the temperature sensor 50 does not detect the temperature defined by a selected cooking program. This could be the case, for example, where a container 110 is too large for the selected burner 10, or an excessively large quantity of product is disposed. 120 to cook in the container 110. The control unit 40 comprises capacitive monitoring means (not shown in the figures) which are electrically connected to the housing 51 of the temperature sensor 50, which acts as an electrode, monitoring said capacitive monitoring means the capacitance of the capacitive detection means 60. In another embodiment of the gas cooking appliance 200 (not shown in the figures), the control unit 40 further comprises transmission means electrically connected to the housing 51 which acts as an electrode, said transmission means emitting pulses of electric current to the electrode, to determine the capacitance of the capacitive detection means 60. In this way, there is no continuous consumption of electric current.
    权利要求:
    Claims (12)
    [1]
    Gas cooking appliance comprising at least one gas burner (10), at least one gas electromagnetic valve (20) which fluently communicates gas from a gas line (30) to the burner (10), a control unit (40) controlling the electromagnetic valve (20), at least one temperature sensor (50) electrically connected to the control unit (40) for measuring a temperature of a cooking vessel (70) disposed in the burner (10), and capacitive detection means (60) of the container (70) comprising at least one electrode electrically connected to the control unit (40), the capacitive detection means (60) being arranged next to the burner (10). ), characterized in that the capacitive detection means (60) comprise the temperature sensor (50), said temperature sensor (50) acting as an electrode of the capacitive detection means (60), and insulating means (90) isolating electrically the temperature sensor (50) d the burner (10).
    [2]
    2. Gas cooking appliance according to claim 1, wherein the insulation means (90) are ceramic material resistant to high temperatures.
    [3]
    Gas cooking appliance according to claim 1 or 2, wherein the capacitive detection means (60) form a capacitor with a capacitance that changes with the presence of the container (70), the control unit (40) being detected capacitance change, and generating an electrical signal that activates the electromagnetic valve (20), moving to a gas flow position open or closed depending on the presence or absence of the container (70)
    [4]
    Gas cooking appliance according to any one of the preceding claims, wherein the temperature sensor (50) comprises a housing (51) constructed of electrical conductive material with low thermal resistance, which is electrically connected to the control unit ( 40) and acts as an electrode of the capacitive detection means (60), generating an electric field (EF) between the housing (51) and a metal part (80) of the gas cooking appliance (200).
    [5]
    5. Gas cooking appliance according to claim 4, wherein the metal part (80) is a grill arranged around the burner (10), the grill being configured so that the container (70) rests on it.
    [6]
    6. Gas cooking appliance according to claim 5 or 6, wherein the housing (51) is connected to the control unit (40) by an electrical connection wire (52).
    [7]
    The gas cooking appliance according to any of claims 4 to 6, wherein the temperature sensor (50) comprises a resistive sensor (53) disposed inside the housing (51) and connected to the control unit ( 40) by two electrical connection wires (55, 56) for transmitting signals of the detected temperature, and a sealant (54) disposed between the housing (51) and the resistive sensor (53), the sealant (54) being a material electrical and non-thermal insulation.
    [8]
    Gas cooking appliance according to any of claims 4 to 7, wherein the insulation means (90) surrounds the housing (51), one end of the housing (51) protruding from said insulation means (90), said end being configured to rest on the outside of the container (70).
    [9]
    9. Gas cooking appliance according to claim 8, wherein the insulation means (90) are arranged inside the burner (10), the housing (51) of the temperature sensor (50) being centered on the burner (10) .
    [10]
    The gas cooking appliance according to claim 9, wherein the burner (10) comprises a burner body (11), and the insulating means (90) comprises a lower guide (91) with a central hole (92). interior passing through it, the lower guide (91) being supported inside the burner body (11), and the temperature sensor (50) being disposed inside the hole (92) and coupled to the lower guide (91). ).
    [11]
    Gas cooking appliance according to claim 10, wherein the insulation means (90) comprises an upper guide (93) with a central inner hole (94) passing through it, and aligned with the hole (92) of the lower guide (91), the upper guide (93) being supported inside the burner body (11) and in the lower guide (91), and the temperature sensor (50) being disposed inside the hole (94).
    [12]
    Gas-cooking appliance according to any of the preceding claims, wherein the capacitive detection means (60) comprise elastic means (61) coupled to the insulation means (90) and the temperature sensor (50), such so that the support of the container (70) in the temperature sensor (50) causes the temperature sensor (50) to back off, compressing the elastic means (61), and maintaining the contact between the container (70) and the sensor temperature (50).
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    同族专利:
    公开号 | 公开日
    CN109210577A|2019-01-15|
    ES2695776B2|2019-11-18|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP0429120A2|1989-11-17|1991-05-29|Whirlpool Europe B.V.|Device for detecting the presence of a food cooking container on a cooking hob|
    US5491423A|1993-03-15|1996-02-13|Whirlpool Europe B.V.|Device for detecting the presence of a food container, such as a saucepan, dish or the like, on a glass ceramic cooking hob|
    EP2180760A1|2008-10-21|2010-04-28|Whirpool Corporation|Method for detecting the presence of a cooking vessel on an induction cooking hob and hob using such method|
    法律状态:
    2019-01-10| BA2A| Patent application published|Ref document number: 2695776 Country of ref document: ES Kind code of ref document: A1 Effective date: 20190110 |
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    优先权:
    申请号 | 申请日 | 专利标题
    ES201730888A|ES2695776B2|2017-07-04|2017-07-04|Gas cooking appliance|ES201730888A| ES2695776B2|2017-07-04|2017-07-04|Gas cooking appliance|
    CN201810711721.1A| CN109210577B|2017-07-04|2018-07-03|Gas cooking appliance|
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