子分类:
- G01G19/002: .{用于邮包或信件}
- G01G19/007: .{将确定重量的材料分成几等分}
- G01G19/02: .用于称量有轮或滚动的物体,例如车辆
- G01G19/08: .与车辆合并一起的
- G01G19/14: .悬挂负载的称量(G01G3/00优先;装在起重机内的称重装置入B66C1/40,B66C13/16)
- G01G19/22: .在混合前配料的称量(比率控制G05D11/00)
- G01G19/387: .用于组合称量的,即选择物品组合的总称量或数目最接近的期望值
- G01G19/40: .具有指示、记录、计算价格或其他与重量有关量的装置的(称量设备的指示装置入G01G23/18;称量设备的记录装置入G01G23/18;一般计算机G06)
- G01G19/44: .用于称量人体的
- G01G19/52: .与其他物品例如与器具相结合的称量器械(与手杖结合的入A45B3/08)
- G01G19/62: .置于上方或下方的称量器械
- G01G19/64: .指示百分比的称量器械,即用于将某一重量表示为预计的或初始重量的百分数
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 181 | Melting furnace equipped with control apparatus corresponding to weight of anode | JP16787088 | 1988-07-07 | JPS6487726A | 1989-03-31 | OTSUTOO SHIYUTENTSUERU; HAINTSU KOONERUTO; RUUDORUFU RANDA |
| 182 | JPS639606B2 - | JP7414981 | 1981-05-19 | JPS639606B2 | 1988-03-01 | HASEGAWA YUTAKA; SHISHIDO YOSHO; EMOTO SHINICHI |
| 183 | Paper monitor system | JP29571286 | 1986-12-11 | JPS62191356A | 1987-08-21 | AARU RANDON UEERUZU; ETSUCHI DABURIYUU KUROORII |
| 184 | JPS61170038U - | JP17999785 | 1985-11-21 | JPS61170038U | 1986-10-22 | |
| 185 | Method and device for weighing material | JP16276784 | 1984-08-01 | JPS6055232A | 1985-03-30 | AARU RANDON UEERUZU |
| 186 | Device for displaying load of hydraulic jack | JP12460383 | 1983-07-11 | JPS6017321A | 1985-01-29 | WATANABE TAKEHISA; MINOWA TATSUO |
| PURPOSE:To display the load values of various kinds of hydraulic jack having different pressure receiving areas by multiplying the pressure of the hydraulic jack by a factor corresponding to the pressure receiving area of the jack by a pressure displaying means. CONSTITUTION:A signal detected by a distortion gauge 1 fitted to the hydraulic jack A is amplified and the pressure and load values are displayed on a digital indicator 9. The indicator 9 is adjusted by span adjusting and zero point correcting variable electric elements 3, 4. The hydraulic jack A, the indicator 9, a pressure sensor B, and a pump F are connected to an Amsler universal tester E to read out the pressure display value of the indicator 9 and a load display value of the Amsler universal tester. Then, a factor regulating variable electric element 7 for multiplying the pressure receiving area of the jack is connected to the indicator 9 through a changeover switch 8 and the factor is adjusted so that digitally displayed value becomes the load display corresponding to the pressure indication. | ||||||
| 187 | Load gage for press | JP1016983 | 1983-01-24 | JPS59135326A | 1984-08-03 | EIANJI HIROSHI |
| PURPOSE:To detect and display an approximate value closest to a true value by a method wherein the load to the maximum level is divided into a plurality of blocks to judge to which block a measured value should belong and a predetermined value is added thereto. CONSTITUTION:A sensor 1 and an A/D converter 2 measures and converts the elongation of a frame into a load value. The elongation of the frame and the load presents a higher-order curve as shown by the curve Z. A discriminator circuit 3 outputs (d) when a measured value exceeds (a)... and D between A and B. Set values of digital switches 21, 22, 23 and 24 are numerals L, M, N and O as illustrated. When the elongation of alpha is detected with the sensor 1, an output (a) is obtained from the discriminator circuit 3 as the load beta is between A and B. An AND gate 17 is opened and the set value L of the digital swtich 21 is inputted into an addition circuit 4 through an OR gate 25 to compute beta+L, which is indicated on a display 26. | ||||||
| 188 | Upper die weight measuring apparatus for press | JP1016783 | 1983-01-24 | JPS59135325A | 1984-08-03 | EIANJI HIROSHI; CHIKAOKA TAKASHI; SERIZAWA KENKICHI; TAGAWA MASAYUKI; KAWAKAMI HIROAKI |
| PURPOSE:To improve the working efficiency of the titled device by searching the weight depending on a load voltage generated when a motor runs with an upper die mounted on a slide to measure the weight of the upper die accurately. CONSTITUTION:An upper die (not illustrated) is mounted on a side (not illustrated) and moved up and down with a slide motor 1. A current transformer 3 is mounted to one wire 2 in a circuit for energization of the slide motor 1 and a current converted to a voltage with an A/D converter 4 is inputted into a microcomputer 5. No-load voltage is memorized in a memory means 6 and then, it is substracted from a load voltage by a subtraction means 7 when the slide motor 1 runs with the upper die on. Thus, the weight is determined with a searching means 9 from the list 8 of weight for the voltage as predetermined. | ||||||
| 189 | System for measuring moisture content | JP445779 | 1979-01-17 | JPS54111889A | 1979-09-01 | UORUFURETSUDO RICHIYAADO REIZA |
| 190 | Shozumibutsupinokaishusurutamenokirokubakari | JP6243875 | 1975-05-23 | JPS512458A | 1976-01-10 | ANRI PITSUTE |
| 191 | SMART SCALE -CULINARY RATIO SYSTEM | PCT/US2014025051 | 2014-03-12 | WO2014151129A3 | 2014-11-13 | WALLACE MICHAEL; ODOM PHILIP T; RICHARDSON BRIAN; BARRI DARIN |
| A system and method for assisting a user in assembling a culinary combination according to a recipe. The system comprises a scale and a computing device configured to communicate with the scale. The system displays information regarding ingredients of the recipe and displays a progress of assembling the culinary combination based on the information from the scale. In some embodiments, a bar graph is displayed with a bar proportional to the measured amount of an ingredient of the recipe compared to a target amount for the ingredient. In some embodiments, the system displays a build column of one or more recipe blocks, representing actions or ingredients of the recipe. An active recipe block is displayed with a portion of the recipe block displayed in a different manner in proportion to the measured amount of an ingredient of the recipe compared to a target amount for the ingredient. | ||||||
| 192 | MULTI-MODE BUTTONLESS SCALE | PCT/US2011051300 | 2011-09-13 | WO2012037063A3 | 2012-05-31 | WONG ANSON |
| A digital scale includes a display and buttonless top platform. Contact with the scale platform alone allows a user to power the scale, identify a user of the scale, determine a mode of operation of the scale, and to establish a reminder. The scale has a user mode of operation displaying a reading of the user's weight. The scale has a pet mode of operation displaying a reading of the weight of a pet. In the user mode of operation a second mode provides a display of the user's current weight, a delta or differential weight with the most recent recorded weight measurement and if the data is available, additional deltas for weight measurements taken up to one year earlier. The scale also has an instant on mode of operation in which it allows for instant weight reading. | ||||||
| 193 | ANALYTICAL FURNACE WITH PREDICTIVE TEMPERATURE CONTROL | PCT/US2004006336 | 2004-03-02 | WO2004081477A3 | 2005-03-31 | WILLIS PETER M |
| An analytical furnace (12) includes a predictive temperature control which is trained to model crucible (24) temperature during analysis by employing a pair of temperature sensors, with one sensor (130) being mounted in the furnace in fixed relationship and a second sensor (140) which can be positioned within a crucible for training and tuning a crucible temperature profile, such that the crucible temperature in which a sample is placed is modeled and its response to the application of energy to the furnace (12) in accordance with the furnace's dynamic thermal characteristics is known. By modeling the temperature profile within a crucible (24), the furnace can be controlled to provide a faster, more accurate analysis and prevent excessive overshooting of temperature as desired temperature plateaus are approached. | ||||||
| 194 | CURVE-CONFORMING SENSOR ARRAY PAD AND METHOD OF MEASURING SADDLE PRESSURES ON A HORSE | PCT/US9406979 | 1994-06-21 | WO9501302A3 | 1995-04-20 | FERRAND ROBERT J; SEMBER JOSEPH A III |
| A sensor array pad (14) for sensing the pressure distribution under a saddle (11) on the back of a horse (12) includes a membrane (25) made of first and second, identical substantially non-stretchable, flexible membrane portions (24). A plurality (16) of sensors (18) are distributed substantially uniformly on the membrane (25), with each sensor (18) occupying a predetermined surface area (60). Conductors (62) are mounted on the membrane (25) to extend between the sensors (18) and a position along the perimeter of the associated membrane portion (24) to provide for external connection with monitoring equipment. The membrane portions (24) further each have a pair (46, 48) of slits extending from a mid-region spaced from the respective facing edge outwardly in diverging directions along lines passing outside the predetermined areas (60) of the membrane (25) occupied by the sensors (18). Pressures sensed by the sensors (18) are input to a computer (76) which generates a display of the pressure distribution. | ||||||
| 195 | DOCKING STATION FOR AN ENTERAL FEEDING DEVICE | EP17704282.7 | 2017-02-15 | EP3416609A1 | 2018-12-26 | THOMPSON, Tomas Martin; MAYNE, Donal; KELLY, Damian |
| A docking station (100) receives an enteral feeding pump (17) or food pod 200 into a cradle with a scales platform (11). The docking station is calibrated to determine nutritional data consumption and remaining available food on the basis of remaining food weight and nutritional data read from a tag using NFC. The station (100) has a sealing sleeve (6) with a sealing rim to confine any spillages in a manner which does not affect weight of the device on a weighting platform. | ||||||
| 196 | BLADE PORTIONER CALIBRATION | EP17703571.4 | 2017-01-23 | EP3405316A1 | 2018-11-28 | HOCKER, Jon, A.; STOCKARD, Richard, D.; BLAINE, George, R. |
| Calibrating the operation of a cutter used in a portioning system to cut workpieces into portions, wherein the workpiece is carried along a driven conveyance device past a scanner and then to a cutting apparatus. The calibration method employs a correction algorithm to correct for variables or limitations in the condition of one or more components of the portioning system and/or variations or limitations in the operation or operational capabilities of the portioning system. The correction algorithm may also factor in the physical condition, configuration, or composition of the workpieces being portioned, as well as whether the workpieces move on the conveyance device prior to and/or during the portioning operation. | ||||||
| 197 | DIGITAL SCALE AND BREWING PROCESS THEREFROM | EP18155400.7 | 2018-02-06 | EP3401653A1 | 2018-11-14 | GROSS, Charles Brian; FEDEWA, Nile Robert |
A digital scale for optimizing coffee brewing, and pour-over brewing in particular, is provided. Specifically, the present disclosure relates to a scale configured to determine the target amount of water to add based an any amount of coffee grounds used, compare an actual pour rate to a target pour rate when adding the target amount of water over a specific target pour time, and clearly communicate the same to the user.
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| 198 | SYSTEM AND METHOD FOR WEIGHING CONTAINERS | EP12780849.1 | 2012-09-21 | EP2760768B1 | 2018-07-18 | CAVINA, Luigi |
| A system for weighing containers includes a movable member having a peripheral edge in which a recess forms a seat for drawing a container, the movable member being activatable in a first movement direction such that a first wall of the seat abuts and draws the container; a container-weighing cell comprising a support plane for receiving and supporting the container; a container guide. The weighing cell, the movable member and the guide are reciprocally arranged such that when the container is drawn by the movable member the container can slide on the support plane and be guided by guide externally of the seat. The movable member is further activatable in a second, opposed, movement direction to detach the seat from the container and leave the container on the support plane for weighing. | ||||||
| 199 | HUMIDITY-DEPENDENT-MASS MEASUREMENT DEVICE AND HUMIDITY-DEPENDENT-MASS MEASUREMENT METHOD | EP15893352.3 | 2015-05-28 | EP3306300A1 | 2018-04-11 | IZUCHI Yukari; KURAMOTO Kanya |
A humidity-dependent-mass measurement device (1) includes: a thermostatic chamber (11) defining an interior space capable of containing a sample, having a through hole, formed in the ceiling and communicating between the interior space and outside, such that an atmosphere of the interior is maintained at a determined temperature and humidity; a balance (12) supported above the thermostatic chamber (11); a measurement tool for suspension from a weighing pan supporter of the balance (12), insertion through the through hole of the thermostatic chamber (11) without contacting an inner circumferential surface of the through hole, and holding the sample in the interior of the thermostatic chamber (11); a cover box (13) including an air inlet port and an air outlet port in a side surface, the cover box (13) containing therein a portion of the measurement tool between the thermostatic chamber (11) and the balance (12) in a state such that the measurement tool is suspended from the weighing pan supporter without contacting the cover box (13); and a dry air supplier (14) for causing dry air at or below a specified humidity to flow into the cover box (13) from the inlet port. |
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| 200 | WEIGHING SYSTEM USING A CONVEYOR BELT | EP15779444 | 2015-03-19 | EP3131840A4 | 2017-12-13 | KLECZEWSKI LAZLO |
| A conveyor belt and a weighing system for weighing articles conveyed on a conveyor belt. The conveyor belt includes an array of force-sensing elements embedded in the belt to measure forces normal to the belt's conveying surface. The force-sensing elements form parts of passive resonant circuits that each include a capacitor and an inductive coil. Either the capacitor or the inductive coil can be a force-sensitive element. Measuring circuits external to the belt include an oscillator having a coil that inductively couples to the resonant circuit in the belt as it passes closely by. A force applied to the belt at a force-sensitive element changes the resonant frequency of its resonant circuit, which also causes a change in the oscillator frequency. Frequency detectors in the measuring circuits measure that frequency change and convert it into a proportional force value used to compute the weights of conveyed articles on the fly. | ||||||
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