子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 具有消毒器的冰箱 | CN201210031642.9 | 2012-02-09 | CN102635995A | 2012-08-15 | 姜圣喆; 张义宁; 郑盛旭; 安宰局 |
| 本发明公开了一种具有消毒器的冰箱,该冰箱根据冰箱内的湿度变化来可变地控制消毒器的操作,以提高消毒能力,该冰箱包括:控制单元,用于在制冷循环期间驱动消毒器同时反复打开/关闭冷空气循环风扇,且用于在除霜加热器操作的期间停止驱动消毒器,其中,在制冷循环期间不操作除霜加热器。 | ||||||
| 2 | 一种超声波解冻设备、方法及其破冰化霜的应用 | CN201710079483.2 | 2017-02-16 | CN106721903A | 2017-05-31 | 曾中苏; 吉洋; 徐斌 |
| 本发明涉及解冻技术,具体说是一种超声波解冻设备、方法及其破冰化霜的应用,其中超声波解冻设备包括机体和设置在机体上的冷冻区,所述冷冻区包括解冻柜和可冷冻食品的冷藏柜,所述解冻柜上设置有超声波解冻装置,该超声波解冻装置将解冻柜内冷冻环境下的冷冻食品上的冻冰震碎,可避免食品中的营养物质随水流失,从而保证了食品的原汁原味,口感好,提高了解冻的效率。本发明的超声波解冻方法可应用于海洋、河流、公路、铁路、桥梁、电力、电信线路的破冰,也可应用于速冻隧道、速冻库、冰箱、空调冷凝器的化霜,不仅破冰时间短、效率高,而且能耗低,操作方便。 | ||||||
| 3 | 空调装置的室外机 | CN201280054622.1 | 2012-11-07 | CN103917829B | 2016-07-06 | 贺川干夫; 小池史朗 |
| 提供一种能迅速将从热交换器滴下的结露水朝外部排出的室外机。在室外机(2)的底框架(26)的热交换器(13)下方形成有排水口(42、44),底框架(26)的基础脚(40)由与底框架(26)的下表面抵接的上板(51b、52b)、固定于设置面(G)的下板(51a、52a)以及将上板(51b、52b)与下板(51a、52a)连接的立板(51c、52c)形成为截面コ字形状,此外基础脚(2)在长度方向上包括第一部分(51)和第二部分(52),第一部分(51)形成为朝水平方向的外侧敞开的截面コ字形状,且其下板(51a)固定于设置面(G),第二部分(52)具有以下结构:至少在基础脚(40)的长度方向上设于与所述排水口(42、44)相对应的位置,并形成为朝水平方向的内侧敞开的截面コ字形状,且其上板(52b)避开排水口(42、44)的下方区域。 | ||||||
| 4 | 空调装置的室外机 | CN201280054622.1 | 2012-11-07 | CN103917829A | 2014-07-09 | 贺川干夫; 小池史朗 |
| 本发明提供一种能迅速将从热交换器滴下的结露水朝外部排出的室外机。在室外机(2)的底框架(26)的热交换器(13)下方形成有排水口(42、44),底框架(26)的基础脚(40)由与底框架(26)的下表面抵接的上板(51b、52b)、固定于设置面(G)的下板(51a、52a)以及将上板(51b、52b)与下板(51a、52a)连接的立板(51c、52c)形成为截面コ字形状,此外基础脚(2)在长度方向上包括第一部分(51)和第二部分(52),第一部分(51)形成为朝水平方向的外侧敞开的截面コ字形状,且其下板(51a)固定于设置面(G),第二部分(52)具有以下结构:至少在基础脚(40)的长度方向上设于与所述排水口(42、44)相对应的位置,并形成为朝水平方向的内侧敞开的截面コ字形状,且其上板(52b)避开排水口(42、44)的下方区域。 | ||||||
| 5 | 急速冷冻装置以及对急速冷冻装置进行消毒的方法 | CN201310060887.9 | 2013-02-27 | CN103292541A | 2013-09-11 | M·卡马塔; M·帕科里奇; F·雷亚莱; F·西纳特拉 |
| 一种急速冷冻装置(1),包括:构造成用于容纳要被冷却/冷冻的食物的急冷室(3);急冷回路(6),所述急冷回路包括至少一第一热交换器(8),第一热交换器设计成对急冷室(3)进行快速冷却/冷冻;除霜系统(12),其设计成对所述第一热交换器(8)除霜;至少一UV源(14),其设计成用紫外线照射所述急冷室(3)的内部空间;以及控制系统,其构造成控制所述除霜系统(12)以加热所述第一热交换器(8),从而使所述急冷室(3)的温度处在所述UV源(14)的预定最佳操作温度范围内。 | ||||||
| 6 | 具有消毒器的冰箱 | CN201210031642.9 | 2012-02-09 | CN102635995B | 2017-11-03 | 姜圣喆; 张义宁; 郑盛旭; 安宰局 |
| 本发明公开了一种具有消毒器的冰箱,该冰箱根据冰箱内的湿度变化来可变地控制消毒器的操作,以提高消毒能力,该冰箱包括:控制单元,用于在制冷循环期间驱动消毒器同时反复打开/关闭冷空气循环风扇,且用于在除霜加热器操作的期间停止驱动消毒器,其中,在制冷循环期间不操作除霜加热器。 | ||||||
| 7 | 用于冰箱的诱霜装置及冰箱 | CN201511030892.0 | 2015-12-31 | CN105526763A | 2016-04-27 | 孙成; 田振华; 李鹏涛; 陈炜; 李高杰 |
| 本发明涉及用于冰箱的诱霜装置及冰箱。具体地,本发明提供一种用于冰箱的诱霜装置,包括诱霜板和第一格栅板。诱霜板配置成用于聚集水汽、且允许水汽在其上凝结成霜。第一格栅板贴设于诱霜板的诱霜表面,且具有允许水汽通过的多个通孔,以将诱霜板的诱霜表面分隔为多个诱霜区域,从而加快了水汽在诱霜板上的聚集速度,提高了诱霜板上的水汽聚集效率,使诱霜板上更容易结霜,进而改善了诱霜装置的诱霜效果。本发明还提供一种冰箱,包括其内限定有储物空间的箱体、用于打开和/或关闭至少部分所述储物空间的门体以及诱霜装置,诱霜装置可拆卸地设置于箱体或门体,以诱使储物空间内的水汽在诱霜装置上凝结成霜。 | ||||||
| 8 | 制冷设备 | CN201510514917.8 | 2015-08-19 | CN105042996A | 2015-11-11 | 周建军; 张华伟; 吴再锐 |
| 本发明公开了一种制冷设备,包括壳体、门体以及冰铲。壳体具有制冷间室,门体设在壳体上以打开或关闭制冷间室。冰铲主要用于对制冷间室进行除冰。冰铲可以包括主体部和适于吸附在壳体上的磁性吸附组件,磁性吸附组件设在主体部的一侧的侧壁上。根据本发明实施例的制冷设备,通过利用磁性吸附组件设在冰铲主体部的一侧的侧壁上,由此可以利用磁性吸附组件的磁力将冰铲吸附在制冷设备的壳体上,方便用户取放,避免冰铲遗失。 | ||||||
| 9 | 具有可运动门的换热器门系统 | CN200980111222.8 | 2009-02-13 | CN101981392A | 2011-02-23 | 小迈克尔·西里尔·哈泽尔迪内 |
| 一种换热器门系统,该换热器门系统包括换热器以及接近于换热器的第一可旋转构件,该第一可旋转构件绕着旋转轴线旋转。该系统包括第一门构件,该第一门构件绕着可旋转构件卷动并且能够从卷起位置运动到展开位置,与当门构件处于卷起位置时相比,该第一门构件在展开位置中覆盖换热器的更多部分。 | ||||||
| 10 | Cooling of a Dewar vessel with ice free coolant and for short sample access | US14417174 | 2013-07-26 | US10066788B2 | 2018-09-04 | Florent Cipriani; Franck Felisaz |
| The present invention relates to a pump (15) for pumping a coolant (9) within a Dewar vessel (1) and to a corresponding Dewar vessel (1) for storing samples in a coolant (9). The Dewar vessel (1) comprises a thermally insulated reservoir (3) for the coolant (9) and a sample vessel (11) provided separately and arranged in the thermally insulated reservoir (3). The reservoir (3) is connected to the sample vessel (11) in such a way that the level of coolant (9) is constant in the sample vessel (11). Pump (15) may help in keeping the level of coolant (9) in the sample vessel (11) constant. For this purpose the pump (15) comprises a chamber (17) with an inlet (19) and an outlet (21), a closing element (23) and a pressure increasing device (25). Therein, the inlet (19) is connectable to the reservoir (3) and the outlet (21) is connectable to a sample vessel (11) of the Dewar vessel (1). The chamber (17) is adapted to fill with coolant (9) through the inlet (19) by gravity and the closing element (23) is adapted to automatically close the chamber (17) when it is full of coolant (9). The pressure increasing device (25) is adapted to increase the pressure within the chamber (17), after the chamber (17) is closed, until the coolant (9) is released through the outlet (21). | ||||||
| 11 | Refrigerator with sterilizer | US13366732 | 2012-02-06 | US09702611B2 | 2017-07-11 | Sung Cheol Kang; Eui Young Chang; Seong Wook Jeong; Jae Koog An |
| A refrigerator which variably controls operation of a sterilizer according to variation in humidity within the refrigerator to improve sterilizing capacity includes a control unit to drive the sterilizer while repeatedly turning the cold air circulation fan on/off during a refrigerating cycle in which the defrosting heater is not operated, and stop driving the sterilizer during operation of the defrosting heater. | ||||||
| 12 | Water-evacuator for air conditioner | US13664026 | 2012-10-30 | US09322570B2 | 2016-04-26 | Daniel W. Hodges; Nallusamy Paraman; Robert Ferenc |
| A system and method for removing condensate from an air conditioning unit is disclosed. A conduit includes an outlet portion that is connected to a chamber of a housing of the unit at a first location, and an inlet portion that is connected to the chamber at a second location where condensate accumulates. A gravitational separator portion which extends below the second location is connected to the outlet portion and the inlet portion. A draining portion having an orifice for allowing condensate to exit the conduit is connected to the gravitational separator portion below the second location. The first location is chosen such that during operation of the unit the pressure at the first location is less than the pressure at the second location. | ||||||
| 13 | REFRIGERATOR | US14803248 | 2015-07-20 | US20160047591A1 | 2016-02-18 | Jin JEONG; Bong Su Son; Do Yun Jang; Yeon Woo Cho |
| Disclosed herein is a refrigerator having a body having a storage compartment; a door to open or close the storage compartment; a cover plate disposed at an inside the storage compartment; a cooling space formed in between the cover plate and an upper wall of the body; an evaporator provided at the cooling space to generate cool air; a blower fan provided at the cooling space to forcedly circulate the cool air generated at the evaporator; a cool air supplying hole formed at the cover plate to supply the cool air of the cooling space to the storage compartment; and a cool air collecting hole formed at the cover plate to collect the cool air heated at the storage compartment to the cooling space, and a rear wall of the storage compartment of the refrigerator may be evenly leveled and usefulness of space may be increased. | ||||||
| 14 | HEAT EXCHANGER DOOR SYSTEM WITH MOVABLE DOOR | US12059678 | 2008-03-31 | US20090242185A1 | 2009-10-01 | Michael Cyril HASELDINE, JR. |
| A heat exchanger door system includes a heat exchanger and a first rotatable member, proximate to the heat exchanger, that rotates about an axis of rotation. The system includes a first door member rolled around the rotatable member and movable from a rolled position to an unrolled position in which the first door member covers more of the heat exchanger than when the door member is in the rolled position. | ||||||
| 15 | Thermoelectric frost collector for freezers | US105778 | 1987-10-07 | US4764193A | 1988-08-16 | Lawrence G. Clawson |
| A thermoelectric heat pump attached to a plate evaporator within the freezer compartment. The surface area of the thermoelectric device is maintained at a temperature substantially lower than the temperature of the evaporator plate during the cooling cycle. Accordingly, the majority of frost is collected on the thermoelectric surface area. Defrost is accomplished by reversing the voltage potential across the thermoelectric device and draining the water away in a suitable manner. | ||||||
| 16 | Efficiency air cycle environmental control system | US508208 | 1983-06-27 | USRE32100E | 1986-04-01 | George C. Rannenberg |
| In a compressed air powered refrigeration system for aircraft containing a refrigeration turbine and associated heat exchangers for supplying cool air to the aircraft cabin, air is recirculated from the cabin by a recirculation means and combined with the turbine discharge air to simultaneously melt ice present in the turbine discharge and provide cooling to the recirculated air. The lack of ice in the turbine discharge allows the use of an ice-free regenerative heat exchanger, in heat exchange relation with the mixture of the turbine discharge air and recirculated cabin air, to condense moisture from the air entering the turbine. The use of heat from the cabin air to melt ice coupled with maximum utilization of the recirculation means supplying the recirculating cabin air enables the turbine to provide air at a temperature below freezing and results in improved cycle efficiency as well as maximum possible ventilation rate to the load. | ||||||
| 17 | Method and apparatus for removing vapors from gaseous mixtures by freezing | US59405766 | 1966-11-14 | US3418820A | 1968-12-31 | SWEARINGEN JUDSON S |
| 18 | High and low temperature refrigeration systems with common defrosting means | US35315464 | 1964-03-19 | US3267689A | 1966-08-23 | LIEBERT RALPH C |
| 19 | Refrigeration apparatus and method | US27660352 | 1952-03-14 | US2641111A | 1953-06-09 | BISHOP ROBERT H |
| 20 | Defrosting and frost prevention | US49520443 | 1943-07-17 | US2342759A | 1944-02-29 | SCHECHTER MILTON S; HALLER HERBERT L J |
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