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    • 2. 发明专利
    • Mh cold water production system
    • MH冷水制造系统
    • JP2014178061A
    • 2014-09-25
    • JP2013051895
    • 2013-03-14
    • Saijo Sangyo Joho Shien Center株式会社西条産業情報支援センターSaijo City西条市
    • OCHI KAZUYUKI
    • F25B17/12
    • PROBLEM TO BE SOLVED: To increase a heat exchanging efficiency between brine and water when water in a water storage tank 20 in an MH cold water manufacturing system is cooled, at the same time simplify a piping and the like, and control an operation and a stopping of an MH freezer device 10 and enable a temperature management for cold water to be carried out.SOLUTION: A heat exchanging coil 14 is arranged within a water storage tank 20, and a brine piping 8 of an MH freezer device 10 and the heat exchanging coil 14 are connected by a connection pipe 14a. Brine is supplied to the heat exchanging coil 14 and directly heat exchanged within the water storage tank 20. An agitator 15 is arranged within the water storage tank 20. Water in the water storage tank 20 is agitated with the agitator 15, uniformly cooled to increase a heat exchanging efficiency and at the same time water is prevented from being frozen. Direct heat exchanging operation improves a responsibility of temperature variation of water in regard to capability of the MH freezer device 10 and enables the temperature management to be carried out.
    • 要解决的问题:为了在MH冷水制造系统中的储水箱20中的水被冷却时,为了提高盐水和水之间的热交换效率,同时简化管道等,并且控制操作和 停止MH冷冻装置10,并实现对冷水的温度管理。解决方案:热交换盘管14设置在储水箱20内,MH冷冻装置10的盐水配管8和热量 交换线圈14通过连接管14a连接。 盐水供应到热交换盘管14并在储水箱20内直接热交换。搅拌器15设置在储水箱20内。储水箱20中的水与搅拌器15搅拌,均匀冷却以增加 热交换效率高,同时防止水被冻结。 直接热交换操作改善了MH冷冻装置10的能力方面的水的温度变化的责任,并且能够进行温度管理。
    • 3. 发明专利
    • Chemical heat pump
    • 化学热泵
    • JP2012083060A
    • 2012-04-26
    • JP2010231218
    • 2010-10-14
    • Ngk Insulators Ltd日本碍子株式会社
    • ARAKI KIYOSHI
    • F25B17/12B01D53/22B01D61/36B01D71/02F25B27/02
    • Y02A30/274
    • PROBLEM TO BE SOLVED: To provide a chemical heat pump utilizing thermal energy by utilizing dehydrogenation and hydrogenation by a facility smaller than before.SOLUTION: The chemical heat pump 50 includes: a dehydrogenation reactor 1 provided with a dehydrogenation section performing the dehydrogenation of a hydrogen containing compound by using thermal energy applied from the outside, and forming a dehydrogenated compound and hydrogen; a hydrogenation reactor 21 forming the hydrogen containing compound by performing the hydrogenation of the dehydrogenated compound by introducing the dehydrogenated compound and the hydrogen formed by the dehydrogenation reactor 1, and outputting the generated reaction heat as thermal energy; and a separating section 41 provided with a separation membrane 44 permeating both the unreacted hydrogen and the dehydrogenated compound sent out from the hydrogenation reactor.
    • 要解决的问题:通过利用比以前更小的设施利用脱氢和氢化来提供利用热能的化学热泵。 解决方案:化学热泵50包括:脱氢反应器1,其具有通过使用从外部施加的热能来进行含氢化合物的脱氢并形成脱氢化合物和氢的脱氢部分; 通过引入脱氢化合物和由脱氢反应器1形成的氢进行氢化脱氢化合物,形成含氢化合物的氢化反应器21,并输出所产生的反应热作为热能; 以及分离部41,其设置有从氢化反应器输出的未反应氢和脱氢化合物两者的分离膜44。 版权所有(C)2012,JPO&INPIT
    • 10. 发明专利
    • Heat utilization system using a hydrogen storage alloy
    • JP3838801B2
    • 2006-10-25
    • JP36056698
    • 1998-12-18
    • リンナイ株式会社
    • 勤 丸橋
    • F25B17/12
    • Y02A30/277Y02B30/62
    • PROBLEM TO BE SOLVED: To put a heat exchanger laminating alloy containers to practical use by laminating a large number of hydrogen occulusion alloy containers while arranging them flatly, forming a heat carrier passage between respective containers and interlinking the adjacent heat carrier passages through a through hole so that heat carrier can be supplied to each heat carrier passage and discharged therefrom. SOLUTION: A heat exchanger 8 comprises a laminate of a large number of flat ring-like discs R in which a plurality of chambers 10 for containing hydrogen occulusion alloy are arranged radially and a heat carrier passage 11 is formed between the alloy containers in the laminating direction. A coupling pipe S5 forming a hydrogen passage S4 and an end closing cover S6 are fixed to the outside of the alloy container. The heat carrier passage 11 is formed between the alloy containers in the laminating direction and the alloy container is provided with through holes A3 in the laminating direction corresponding to respective ranges of the first, second and third containers S1, S2, S3. Each heat carrier passage 11 communicates with the adjacent heat carrier passage 11 through the through hole A3.