| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 81 | Electronic integrating meter | JP11149783 | 1983-06-21 | JPS603795A | 1985-01-10 | MIHARA YUUJI |
| PURPOSE:To change counting operation optionally by providing a signal circuit, which switches a phase positively and negatively between a detecting circuit and a positive/negative discriminating circuit in an integrating circuit which counts the number of pulse signals corresponding to the quantity of used fluid. CONSTITUTION:A magnet 13 is rotated together with a rotary blade 15 provided in a flow passage, and its magnetic flux is converted to a voltage by a detector 14 to obtain a pulse signal. The first pulse signal P1 and the second pulse signal P2 having a prescribed phase difference are provided with this pulse signal for the purpose of discriminating the rotation direction of the rotary blade, and these pulse signals are shaped by a detecting circuit 1 and are inputted to a signal switching circuit 7. The circuit 7 consists of a logic gate and reverses the phase relation between both pulse signals P1 and P2 in accordance with the logic of a control signal CT. The signals are inputted to a positive/negative discriminating circuit 2 to decide addition or substraction in accordance with the phase relation between them, and they are counted by an integrating circuit 4 after passing a converting circuit 3, and the counted value is not only displayed on a display device 6 through a display circuit 5 but also is transmitted to an external device from a signal line 11 through a transmitting circuit 10. | ||||||
| 82 | Reader for weighing value | JP5412384 | 1984-03-21 | JPS59180334A | 1984-10-13 | MANFUREETO SHIYUBUENTONAA; BUIRUHERUMU SHIYUTEYURUTSURU |
| 83 | JPS52103876U - | JP16220676 | 1976-12-03 | JPS52103876U | 1977-08-06 | |
| 84 | JPS4838173A - | JP7269272 | 1972-07-21 | JPS4838173A | 1973-06-05 | |
| 85 | PASSIVE MONITOR FOR INTEGRATED CIRCUIT COMPONENTS | US15801531 | 2017-11-02 | US20180306848A1 | 2018-10-25 | Chee Guan Ho; Wee-Liang Lien; Chee Hong Yong; Geok Teng Ong; Chin-Heng Leow |
| A parameter monitor and method for monitoring a parameter of a passive component on an integrated circuit. The parameter monitor includes an oscillator circuit. The parameter monitor also includes circuitry configured to measure a first time period of an oscillation of the oscillator circuit with a passive component to produce a first digital count value, to measure second time period of an oscillation of the oscillator circuit without the passive component to produce a second digital count value, and generate a code indicative of a value of or a variation in the value of the passive component using the first and second digital count values. | ||||||
| 86 | METHOD FOR COUNTING CORDS IN RUBBER SHEET | US15769499 | 2016-10-24 | US20180306576A1 | 2018-10-25 | Junki FUNANE |
| To count cords embedded in a rubber sheet with good working efficiency while improving the reliability and accuracy, a method includes a step S1 of acquiring raw waveform data D1 by scanning the outer surface of the rubber sheet with a displacement sensor, a step S2 of obtaining first corrected data D2 by performing a moving average processing on the raw waveform data D1, a step S3 of obtaining second corrected data D3 by converting the amplitude center j of waveform of the first corrected data D2 into a straight line, a step S4 of obtaining concave-center-position data D4 in which the concave-center-positions Q between the cords are defined by positions of lowest points of valleys of the waveform of the second corrected data D3, a step S5 of obtaining first corrected concave-center-position data D5 in which, by comparing intervals K between the Q with an upper threshold Kmax and lower threshold Kmin therefor, the concave-center-positions Q are added/deleted, and a step S5 of obtaining second corrected concave-center-position data D6 in which, by comparing the total number (m) of the concave-center-positions Q in the first corrected concave-center-position data D5, with the number (n) of the cords 3, the concave-center-positions Q are added/deleted. | ||||||
| 87 | Method and system to count movements of persons from vibrations in a floor | US15864026 | 2018-01-08 | US10062028B2 | 2018-08-28 | Thomas Danaher Harvey |
| A system and method for counting persons using passages entering or exiting an area by analyzing vibrations in the floor with sensors and a machine learning system. The machine learning system uses a model, usually implemented as a neural network on a processor. The network is trained in levels and implemented in layers. Different levels classify and analyze vibrations by timing and frequency, by movements of persons, and by identity of persons The same person is identified by patterns in the vibrations and the vibrations are correlated to determine when a person uses a combination of passages and is thereby counted. Location information for the person is used to identify persons in places and doing activities of interest. The model may be trained on one processor and then downloaded to another processor for evaluation. Additional sensors and levels of training may be implemented on the latter processor. | ||||||
| 88 | METHOD AND DEVICE FOR DETECTING UNAUTHORIZED TRANFER BETWEEN PERSONS | US15828629 | 2017-12-01 | US20180101757A1 | 2018-04-12 | Thomas Danaher Harvey |
| A method of confirming the identity of a person who issued a token to signify eligibility for a privilege. Possession token is confirmed to be by the same person by using sensors in the token which track the movements of the person. A machine learning system is trained to evaluate the sensor data detecting transfer of possession of the token. The state of continuous possession since the token was issued or set to an enabled state is confirmed and the privilege is granted. The method of identity confirmation is used in various contexts such as for to control entry to a location, use of a facility or service. It is also useful to determine continuous possession of a weapon to prevent misuse after the weapon is stolen, dropped or lost. Servers, beacons and outside sources of data or inputs to be measured by the sensor can also be used. | ||||||
| 89 | Point-of-care hygiene compliance module | US14995481 | 2016-01-14 | US09770141B2 | 2017-09-26 | Jackson W. Wegelin; Matthew J. Archer |
| A point-of-care hygiene compliance module includes a housing that is adapted to be attached to a dispensing container that dispenses material through a dispensing nozzle when actuated. The housing includes a pivoting actuation arm that is configured so as to be placed in operative contact with the dispensing nozzle. Thus, when the actuation arm is actuated, material is dispensed from the dispensing container, and a switch in operative contact with the actuation arm is actuated. The triggering of the switch updates a count value that is maintained by a controller, which may then be displayed or acquired by a remote computer to assess the amount of usage of the dispensing container. | ||||||
| 90 | POINT-OF-CARE COMPLIANCE MODULE | US13833525 | 2013-03-15 | US20140197194A1 | 2014-07-17 | Jackson W. Wegelin; Matthew J. Archer |
| A point-of-care hygiene compliance module includes a housing that is adapted to be attached to a dispensing container that dispenses material through a dispensing nozzle when actuated. The housing includes a pivoting actuation arm that is configured so as to be placed in operative contact with the dispensing nozzle. Thus, when the actuation arm is actuated, material is dispensed from the dispensing container, and a switch in operative contact with the actuation arm is actuated. The triggering of the switch updates a count value that is maintained by a controller, which may then be displayed or acquired by a remote computer to assess the amount of usage of the dispensing container. | ||||||
| 91 | PRESSURE-INDUCED COUNTER | US12238411 | 2008-09-25 | US20090262883A1 | 2009-10-22 | CHUN-NAN OU; HU XIE; CHENG-BIN SU; JIAN-LONG XING; SHUI-HUA CHENG |
| A pressure-induced counter includes a pressure acquisition unit, a delay unit and a counter unit. The pressure acquisition unit is electrically coupled to the counter unit via the delay unit. The pressure acquisition unit is configured for acquiring a pressure signal of an external pressure applied thereon to generate and output an original electrical signal corresponding to the pressure signal. The delay unit is configured for processing the original electrical signal outputted from the pressure acquisition unit to obtain a processed electrical signal by depressing the leading-edge jitter existing therein. The counter unit is configured for receiving the processed electrical signal transmitted from the delay unit and taking count of the received signals. | ||||||
| 92 | Capacitive number wheel encoder for utility meters | US298641 | 1994-08-31 | US5554981A | 1996-09-10 | Ronald N. Koch; Richard H. Koch; Ray J. Thornborough |
| A number wheel assembly (10) for a counter mechanism has a plurality of number wheels (13-18), each number wheel (13-18) having a sleeve (48) around its circumference with a plurality of positions representing successive increments in a count, a substrate (26-31) opposite one surface of the number wheel (13-18), the substrate (26-31) carrying an electrode (42) that is spaced from the number wheel (13-18) to form an air gap for a variable capacitor, and wherein the number wheel (13-18) carries at least one dielectric element (46) that is rotated with the number wheel (13-18) to vary the capacitance of the variable capacitor according to the position of the number wheel (13-18). Circuitry for detecting the capacitance and the position of the number wheels (13-18) is provided on a circuit board (39) that is electrically connected to the number wheels (13-18). | ||||||
| 93 | Inductive coupling system for the bi-directional transmission of digital data | US505032 | 1983-06-20 | US4758836A | 1988-07-19 | Felice M. Scuilli |
| A bi-directional, digital data transmission system is disclosed for transmitting an interrogation signal in a first direction from an interrogation unit to a data gathering transponder unit, and a data return signal in a second direction from the meter or data gathering transponder unit to the interrogation unit. This system comprises a single transformer having a primary winding coupled to the interrogation unit and a secondary winding coupled to the transponder unit. The interrogation unit generates an interrogation signal comprised of a first train of regularly occurring digital clock pulses and transmission interval pulses, each transmission interval pulse defining a transmission interval for the transmission of the data return signal. The transmission interval is set to be of a sufficient length to permit the transformer to desaturate to a level to permit efficient transmission of the data return signal to the interrogation unit. The transponder unit includes a data transmitting circuit responsive to the transmission interval pulses appearing at the secondary winding for generating and applying, during the transmission intervals, digital signals indicative of the gathered data to the secondary winding to be transmitted via the transformer to the interrogation unit. | ||||||
| 94 | Meter data gathering and transmission system | US510753 | 1983-07-01 | US4652877A | 1987-03-24 | Bruce E. Gray |
| A utility data gathering system is disclosed as comprising a register including a series of index members coupled to a meter mechanism. Each index member includes a plurality of contacts and a switch arm moveable with its index member. The meter mechanism is responsive to utility consumption for moving the index members to positions indicative of the utility consumed, whereby each switch arm completes in normal operation a circuit with just one of its plurality of contacts dependent upon the position of its index member. A digital computer is programmed for performing first and second scans of each contact of each index member to obtain corresponding first and second sets of data indicative of a completed circuit through the switch arm and contacts of each index member. The completed circuit data obtained from each of the first and second scans are compared and if the circuit data of the first and second scans are different, an alarm manifestation is generated. | ||||||
| 95 | Apparatus for electronically reading mechanical meters having non-simultaneously changing digits | US315148 | 1981-10-26 | US4437098A | 1984-03-13 | Shlomo Rosinek; Isaac Rinkewich; Boris Khurgin |
| The digits of the meter are each represented by the position of a member rotatable to one of ten different positions. The positions of the members do not change simultaneously. A set of first and second sensors are provided for each member. Each sensor is effective, when actuated, to sense the position of the member associated therewith. In each set, the first and second sensors are spaced apart, along the direction of movement of the member, by a distance less than the distance between adjacent positions of the member. The first sensor in each set is actuated, in sequence, to detect the position of the corresponding member and to generate a code representative of the sensed position. The codes for the first meter reading are converted into a first number, which is stored. After a delay sufficient to permit all of the members to change position, the second sensor in each set is actuated, in sequence. Each of the second sensors generates a code representative of the position of the corresponding member. The codes from the second meter reading are converted into a second number and stored. The stored numbers are then compared and the appropriate one selected. | ||||||
| 96 | Converter of meter-gauge readings | US128352 | 1979-07-09 | US4336447A | 1982-06-22 | Yuzo Oguchi; Takayuki Itakura; Akio Kawano |
| A quantity converting and indicating apparatus for use in automatic remote systems for inspecting consumed amounts of gas, city water, electric power or the like, by which a detected value in the decimal system displayed on such a counter as a gas meter is converted to a binary system value convenient for transmission by a channel such as a telephone circuit. The apparatus is provided with plural cams (2) cooperative with a figure wheel (4) of the counter for converting the detected value to the binary system value, plural vibrators (6a) placed facing each cam and fixed each at one end, flexible vibrator controlling members (5) placed adjacent to the concaves and convexes (2a, 2b) of each cam and facing the respective vibrators at their other ends for controlling the vibrators, means (10) for activating the vibrators, and means (7, 8) for converting the vibration to an A.C. signal having a frequency in a band adopted for transmission by means such as a telephone circuit. | ||||||
| 97 | Meter particularly measured quantity read-out device therefor | US3723711D | 1971-05-20 | US3723711A | 1973-03-27 | KAMATA T |
| A measured quantity readout device for use with flowmeters and the like comprising means for producing electrical signals indicative of the measurement of a predetermined quantity of flow; a motor adapted to be actuated by the electrical signals and driving a digit wheel which is provided with coded elements on its periphery for indicating the quantity of flow; two sets of contacts mounted on respective support plates and urged toward each other by a spring such that each engages the digit wheel in diametrically opposed positions on its outer periphery to sense the presence or absence of the coded elements; output lines for reading out signals indicating whether either or both of the sets of contacts are closed by the sensing of a coded element; and means operated by the motor for urging the sets of contacts out of engagement with the digit wheel to render the wheel free to be driven by the motor during its actuation by the electrical signals. Alternate embodiments of the latter means are disclosed and the details of one form of signal-producing means.
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| 98 | Code transmitter having intermittent drive mechanism | US3675237D | 1970-03-02 | US3675237A | 1972-07-04 | WEINFURT WILLIAM J |
| An intermittent drive mechanism for an encoding device is driven by a continuously rotating drive source. First and second Geneva drive discs are each rotated through a sequence of rotated rapid incremental displacements to a plurality of positions each of which are utilized for providing coded information. The first Geneva drive disc is rotated by a drive means which is moved to a high energy level condition by the drive source and permitted to rapidly discharge. A second drive means is connected to the first disc and is moved to a high energy level condition by rotation of the first disc and permitted to discharge to rapidly drive the second disc.
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| 99 | Electro-mechanical readout device | US30478063 | 1963-08-27 | US3268712A | 1966-08-23 | LEE HAROLD G; ALLEN HOWARD M |
| 100 | Halogen containing polyurethane foams and preparation of same | US85368959 | 1959-11-18 | US3055850A | 1962-09-25 | MICHAEL WORSLEY; HINDERSINN RAYMOND R |
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