| 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 | 一种水表生产设备挡板 | CN201610667493.3 | 2016-08-15 | CN106098108A | 2016-11-09 | 郭春松; 黄汉生 |
| 一种水表生产设备挡板,包括:横板、垂直挡板、竖槽、卡槽、电路控制板、手柄,所述横板与电路控制板连接,所述电路控制板上设有8个档位按钮,所述横板上方设有垂直挡板,垂直挡板上设有两个竖槽,所述竖槽上设有8个卡槽,所述电路控制板的上方设有手柄,手柄可以180度旋转,本发明可自动控制挡板的高度,根据不同档位进行调整,使用操作自动化,并且运用在紫外线设备中起到了保温遮挡的效果,此结构简单,便于普及。 | ||||||
| 2 | Measuring arrangement | US32010 | 1993-03-16 | US5426428A | 1995-06-20 | Hans Binder; Gerd Lohninger |
| A measuring arrangement for autoclaves or similar arrangements under heavy climatic conditions includes at least one measuring probe, a measuring electronics connected with the measuring probe via a connection line and arranged in a thermally insulated container. The measuring electronics includes a transmitter unit to which a transmitting antenna is associated, which is arranged outside of the container on a lid provided therefor and is connected via a connection line. A separate receiver unit is associated with a receiving antenna. The thermally insulated container contains two oppositely oriented Dewar vessels arranged one within the other, the inner Dewar vessel accommodating the measuring electronics. The connection lines are led through the interspace between the Dewar vessels and are connected to a coupling tightly provided in the lid. A corresponding coupling is associated with the coupling means for connecting the transmitting antenna and the connection line to the at least one measuring probe. The measuring electronics includes an analog/digital converter for digitalizing the measured data as well as a digital control and processor module followed by the transmission unit. | ||||||
| 3 | Shelter | US949382 | 1978-10-06 | US4263963A | 1981-04-28 | Alberto Ghiraldi |
| The invention concerns a shelter device in the form of a box-like structure for the protection of electronic apparatuses against atmospheric agents.The shelter comprises walls of insulating material forming a thermal resistance, as well as an amount of material(s) having a high specific heat operating inside the structure and forming a thermal capacity, the thermal resistance and capacity being able to maintain a shelter inner temperature that is constant and is correlated to the outer mean temperature over a time period of at least 24 hours. | ||||||
| 4 | Method and apparatus for protection against heat | US270793 | 1988-11-14 | US5009514A | 1991-04-23 | Ardon Gador |
| A method for slowing the heat transfer rate to a flow facing part of an object exposed to a high total enthalpy fluid flow flowing in a direction approximately perpendicular to that part, including the step of recessing that part. There is also provided apparatus for protecting a heat sensitive instrument (26) in an object (20) from a high enthalpy fluid flow impinging on the instrument in flow facing relationship, and to which the instrument must be exposed due to the nature of its desired functioning, including an essentially unvented recess (22) defined in or near the tip or the leading edge of the object, the instrument being disposed in the recess. | ||||||
| 5 | Heat-insulated telemetry system for vacuum furnace | US788238 | 1985-10-17 | US4688039A | 1987-08-18 | Michael A. Berk |
| A heat-insulating box houses a telemetry system of high accuracy for use within a high-temperature vacuum furnace. The container includes an inner box formed by a block of rigid heat-insulating material having a cavity which contains a telemetry system chassis and its components, including such items as batteries, transmitters, switches, thermocouple elements including transition tubes, isothermal double-layer terminal strips, and the like. A plurality of very fine thermocouple conductors of dissimilar metal extend from the thermocouple junction tips on work pieces outside of the box through the heat-insulating inner block to the thermocouple transition tubes, and then, by way of the isothermal double-layer terminal strip to the transmitters. An antenna lead is carried through the wall of the box to a transmitting antenna mounted on the front wall of the box. Pressure switches in the cavity within the box control the ON-OFF condition of the transmitters. These pressure switches are normally open and do not close until the pressure falls to a vacuum pressure corresponding to the pressure in the vacuum furnace, and the switches open when the pressure rises to a preselected value. Thus, the transmitters are ON for only a portion of a complete work cycle. Battery energy is conserved and battery life extended. Various features of the construction of the telemetry box and its contents contribute toward insulating the telemetry transmitters from the high heat of the furnace. | ||||||
| 6 | TITANIUM ALLOY (10V-2Fe-3Al) FOR AIRCRAFT DATA RECORDER | EP85902722.0 | 1985-01-14 | EP0169242A1 | 1986-01-29 | WHITE, William, F.; SPURR, William, F. |
| Une boîte (12) pour l'enregistreur des données de vol d'un aéronef est constituée à l'aide d'un alliage de titane ayant une composition nominale de 10% en poids de vanadium, 2% en poids de fer et 3% en poids d'aluminium, le solde étant du titane et, dans des limites, certains éléments à l'état de trace. L'alliage est transformé de préférence par forgeage en une enceinte (12) d'enregistreur par un procédé de forgeage isothermique en deux étapes. Le travail lors de la première étape a lieu à une température supérieure au point de transition bêta, tandis que le travail lors de la seconde étape s'effectue à une valeur proche mais inférieure au point de transition beta. Il est préféré que 70 à 90% environ de la matière introduite dans l'enceinte (12) pendant le forgeage isothermique soit introduit lors de la seconde étape de travail. Des traitements thermiques ultérieurs combinés avec le processus décrit ci-dessus se traduisent par une microstructure recristallisée à grain fin ayant une frontière alpha à grain discontinu qui confère à l'alliage une haute résistance à la pénétration. | ||||||
| 7 | Messwerterfassungseinrichtung | EP86112015.2 | 1986-08-29 | EP0231431A1 | 1987-08-12 | Sommerer, Jürgen; Hagens, Hajo; Kainer, Hartmut, Dr. |
Eine Meßwerterfassungseinrichtung an einem Durchlaufofenwgen weist in einem Temperaturschutzgefäß eine batteriebetriebene Meßwertspeicherschaltung auf. Um diese erst kurz vor der Einfahrt in den Durchlaufofen starten zu können, ist im Temperaturschutzgefäß (2 bis 7) eine Einschaltschaltung (16,17,18) angeordnet, die beim Anlegen einer Spannung (26) die Meßwertspeicherschaltung (13) einschaltet. Eine Steuerleitung (22) zur Betätigung der Einschaltschaltung (16) endet außen am Durchlaufofenwagen (1). |
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| 8 | SHIELDING BODY, AND SUPERCONDUCTING ACCELERATOR | US15576595 | 2016-05-19 | US20180153028A1 | 2018-05-31 | Hiroshi HARA; Katsuya SENNYU |
| This shielding body for shielding from geomagnetism and radiant heat comprises: a magnetic shield portion having a plate shape formed from a magnetic body; and a radiation shield portion formed as a film on at least one among outer and inner surfaces in the magnetic shield portion, and formed from a material having a greater heat conductivity than the magnetic body. | ||||||
| 9 | Composite heat shield | US400888 | 1982-07-22 | US4438168A | 1984-03-20 | Olivier Testard |
| The shield comprised at least one thermally insulating assembly formed by a reflecting layer and a spacing layer in which the latter is a knitted product. Preferably, the knitted product is tulle, for example of polyester or polyimide, produced by using a monofilament thread. The production process consists of preferably simultaneously performing the cutting of the reflecting layer and the spacing layer so as to form the edges for the said layers and the welding together thereof by these edges, the cutting and welding processes being performed hot.Application to the thermal insulation of cryogenic instruments carried on spacecraft. | ||||||
| 10 | Automatic readout micrometer | US45170 | 1979-08-04 | US4320577A | 1982-03-23 | Ted Lauritzen |
| A measuring system is disclosed for surveying and very accurately positioning objects with respect to a reference line. A principal use of this surveying system is for accurately aligning the electromagnets which direct a particle beam emitted from a particle accelerator. Prior art surveying systems require highly skilled surveyors. Prior art systems include, for example, optical surveying systems which are susceptible to operator reading errors, and celestial navigation-type surveying systems, with their inherent complexities. The present invention provides an automatic readout micrometer which can very accurately measure distances. The invention has a simplicity of operation which practically eliminates the possibilities of operator optical reading error, owning to the elimination of traditional optical alignments for making measurements. The invention has an extendable arm which carries a laser surveying target. The extendable arm can be continuously positioned over its entire length of travel by either a coarse or fine adjustment without having the fine adjustment outrun the coarse adjustment until a reference laser beam is centered on the target as indicated by a digital readout. The length of the micrometer can then be accurately and automatically read by a computer and compared with a standardized set of alignment measurements. Due to its construction, the micrometer eliminates any errors due to temperature changes when the system is operated within a standard operating temperature range. | ||||||
| 11 | Measuring temperature in a very-high temperature environment | US44438674 | 1974-02-21 | US3880007A | 1975-04-29 | EMSCHERMANN HANS HEINRICH; FUHRMANN BRUNO; HUHNKE DIETER |
| A temperature-sensitive unit operative for generating an analog temperature-indicating electrical signal is placed in the veryhigh-temperature environment and generates a signal indicative of the temperature to which it is exposed. Also placed in the veryhigh-temperature environment is a heat-insulating container containing an electrical-energy-consuming electronic buffer storage circuit generating heat during operation and protected by the container from the heat of the very-high-temperature environment. The electronic buffer storage circuit is electrically connected to the temperature-responsive unit and is operative for receiving the analog temperature-indicating signal and temporarily storing a corresponding signal indicative of the value of the analog temperature-indicating signal. Subsequently, the electronic buffer storage circuit is brought into a cooler environment and is there connected to an electrical-energyconsuming readout device, such as a digital display device which generates heat during operation, and the stored signal is read out. This results in a slower build-up of temperature in the heat-insulating container than if the read-out device were incorporated therein. The electronic buffer storage circuit can include an analog-to-digital converter circuit, and preferably is a very small electronic circuit having a very low heat generation rate, to minimize the rate of temperature build-up in the heatinsulating container.
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| 12 | JPH0373734B2 - | JP5733083 | 1983-03-31 | JPH0373734B2 | 1991-11-22 | YOKO TAKEJI; NAKAGAKI AKIZUNA; MYAZAWA AKIO |
| 13 | Optical measuring device | JP25786184 | 1984-12-06 | JPS61134608A | 1986-06-21 | SHIMOYAMA HIROSHI; EMOTO MITSUTAKA |
| PURPOSE:To perform the measurement stably with a high precision even in high-temperature and high-humidity circumstances by storing a detector in a double case and cooling the inside case to a prescribed temperature. CONSTITUTION:The first case 6 where a detector 5, which projects light to an object to be measured from a hood 50 under the object to measure its properties, is stored and a heat insulating material 60 is provided on the inside is stored in the second case 7. A dry air A is supplied into the case 7 from the external, and this air A is branched into three by manual valves 81, 82, and 83, and the air from the manual valve 81 is supplied to a cooling part 10 through a solenoid valve, the an air A1 from the valve 82 is released to the case 7, and an air A3 from the valve 83 is supplied to the detector 5 in the case 6. A cooled air A2 cooled by the cooling part 10 is supplied to the case 6 and is charged into the case 7 and is discharged out of the case 7 from the outside peripheral part of the hood 50 together with the air A1 from the manual valve 82. The air A2 from the cooling part 10 keeps the temperature in the case 6 constant by turning on and off a solenoid valve 9 with a control means 11 including a temperature detector 110 in the case 6. | ||||||
| 14 | Heat shielder and its manufacture | JP13230982 | 1982-07-30 | JPS5850493A | 1983-03-24 | ORIBIE TESUTAARU |
| 15 | シールド体、及び超伝導加速器 | JP2015110877 | 2015-05-29 | JP2016225156A | 2016-12-28 | 原 博史; 仙入 克也 |
| 【課題】省スペース化及び取扱いの簡便化を図りつつ、十分なシールド特性を得ることのできるシールド体、及びシールド体を備えた超伝導加速器を提供する。 【解決手段】地磁気と輻射熱のシールドを行うシールド体4であって、磁性体によって形成された板状をなす磁気シールド部11と、磁気シールド部11おける内外の表面11aのうちの少なくとも一方に成膜されて、磁性体よりも熱伝導率の大きい材料によって形成された輻射シールド部15とを備えている。 【選択図】図2 |
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| 16 | JPS5520178B2 - | JP1704374 | 1974-02-12 | JPS5520178B2 | 1980-05-31 | |
| 17 | Electronic range | JP1489577 | 1977-02-14 | JPS52112842A | 1977-09-21 | KURISUTEIAN RIIMERU; DONARUDO HERUMAN; HAINRITSUHI SHIYUTORUKU |
| 18 | JPH034087B2 - | JP25786184 | 1984-12-06 | JPH034087B2 | 1991-01-22 | SHIMOYAMA HIROSHI; EMOTO MITSUTAKA |
| 19 | Heat insulation device | JP5733083 | 1983-03-31 | JPS59183033A | 1984-10-18 | YOKO TAKEJI; NAKAGAKI AKIZUNA; MIYAZAWA AKIO |
| PURPOSE:To improve a heat insulation characteristic and prevent the interior of heat insulation container from overheat, by providing a heat insulation layer made of heat regenerative material and a wickless type heat pipe in the heat insulation layer, in a heat insulation container including a control device therein. CONSTITUTION:A heat insulation chamber 6 having a heat regenerative material is provided at the inner surface of upper and lower cases 2, 3. A control device 7 is provided inside an accommodating chamber 8. One end of wickless type heat pipe 9 is inserted into a heat insulation layer 6, having its other end projected outwardly from the heat insulation layer 6. By so arranging, a heat stored in the heat regenerative material 5 of heat insulation container can be dissipated in a short period for improving its heat insulation characteristic. Additionally, the interior of heat insulation container will not be heated up inadvertently. | ||||||
| 20 | JPS49118476A - | JP1704374 | 1974-02-12 | JPS49118476A | 1974-11-12 | |
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