CS207494B1 - automatic climatologic station - Google Patents

Description

The invention relates to an automatic climatological station with a fully automatic recording of several different selected meteorological parameters and to measuring the time for reading these parameters on a single punched tape, comprising sensors of solar radiation, temperature, humidity, rain and wind speed, wind direction anemometer signals and an analog-pulse signal converter that converts the value into an electrical pulse, allowing the device in the form of a contact block to transmit information about the measured value of the meteorological parameter, the station is powered from its own DC source plus four sensors transmitting the value signal physical quantities in analog form are connected to the analog-pulse signal converter via the control unit and two sensors transmitting the signal of physical quantity in the form of of the electrical pulse are directly connected to each of their respective wind and rain speed integrators, each of which is in turn connected to the control unit and the encoder.

Climate is an important element of the geographical environment affecting the development of organic life and, to a large extent, the human economy. Knowledge and rational use of the climate require systematic and long-term measurements of basic meteorological parameters. These parameters, after averaging over a long period of time, characterize the climatic conditions. Measurements of this kind are carried out in climatological stations. The network of these stations in the country, dense enough to determine the general characteristics of the country, is not sufficient to explore the climate of smaller areas, which is now becoming a more practical problem.

Climatological stations known and used so far are designed as non-automatic or semi-automatic equipment. Recording of meteorological elements is performed by reading the measured values or recording with ink on paper tapes, which requires a lot of time-consuming reading of the values of the elements recorded on these tapes. Readings of meteorological elements are manually entered on paper forms. Their introduction into computers for statistical processing also requires manual punching of all values. Frequent maintenance is also required on this equipment. This is usually done by different manufacturers, making it difficult to repair and maintain the equipment.

The prior art in the field of meteorological and khmatological instruments is described in the book "Methods and Measuring Instruments in Meteorology and Hydrology", written by E. Strauch, Polish Scientific Publications, Warsaw 1972, in particular on pages 238 to 243.

This object has been achieved and the disadvantages of the prior art have been eliminated by the automatic climatological station according to the invention in that its sensors transmitting the physical value signal in analog form are connected to an analog-pulse converter via its control unit and its sensors transmitting the physical value signal in electrical form. The pulse is connected directly to its respective integrator, each of which is connected to the control unit and encoder, and the common shaft connects the drive, the tape puncher and the analog-to-pulse converter and has a shaft circuit to turn it on at programmed time intervals. the converter, each of the two integrators, the time meter and the anemometer for measuring the wind direction with the wind direction sensor are connected to an encoder common to all of them, which passes the processed information in a programmed code m punching tape system. The switch-on unit of the station consists of a clock whose selected hand is equipped with a small mirror and the edge of the clock face is fitted with an iodine placed between two dwarf bulbs. The photodiode electrical circuit is connected to the traction motor control unit and the control unit via an amplifier.

The station integrators are equipped with two solenoids and one of them is connected to the sensor electrical circuit. The second electromagnet is then connected to the electrical circuit of the control unit from which it receives pulses at eight minute intervals, the first core of the first electromagnet being connected to a single-arm lever. The lever is provided with a first ratchet latch that is loosely mounted on the first shaft. This shaft is also provided with a loose toothed clutch plate fixedly connected to the ratchet, and a second plate is fixedly connected to the first shaft, on which the first contact hand is rotatably mounted relative to the multi-segment plate relative to the multi-segment plate. The two shorting contacts of this handle are located one on the first metal ring of the integrator board, the other opposite mutually insulated segments arranged along the board edge, whereby the ring or ring and each segment are connected to the coding via separate galvanic circuits.

The station time meter is equipped with a third solenoid whose coil is connected to the control unit. The second core of the electromagnet is then connected to another single-arm lever to which is attached a second latch of the second ratchet mounted on the second countershaft. Then, the second contact hand is rotatably mounted to the second plate to rotate the shaft. The handle is provided with two shorting contacts, one of which is located on the metal ring of the other plate and the other opposite mutually insulated segments arranged along the edge of the plate. The second ring and each segment is connected via a separate galvanic circuit to the coding.

The station according to the invention consists of known, partially modified or brand new units suitably interconnected and allowing fully automatic recording of several selected meteorological data on a single common punched tape. Information supplied by one of the weather sensors, such as a thermometer, is recorded on a punched tape that can be stored in the station until it is transmitted to a computer or can be transmitted to a central office by trunk. After processing in a computer, the customer can receive the measurement results in the form of printed sheets containing, for example, the measured temperature profile over hours.

This measurement limits the participation of people in meteorological measurements, when reading record tapes and in statistical processing of results. This brings considerable savings in the work of experts and makes the automatic climatological stations arranged according to the invention many times cheaper than traditional stations.

Further advantages of the invention will be discussed in the description of an exemplary embodiment of an automatic climatic station according to the invention, which is shown in the accompanying drawings, in which Fig. 1 shows a block diagram of a climatological station; Fig. 2 schematic diagram of a particular assembly including joints; Fig. 4 shows the same circuit at the moment of switching on the photodiode, Fig. 5 shows the integrator side view, Fig. 6 shows the integrator side view, Fig. 7 shows the integrator board side view, Fig. 8 shows the time meter side view and Fig. 9 shows the time meter dial side view.

Analog signals (see Fig. 2) received from meteorological sensors - from thermoelectric battery 1, showing the intensity of solar radiation, from resistance thermometer 2, showing air temperature, from resistance thermometer 3, showing earth temperature, and from membrane hygrometer 4, showing air humidity - are transmitted via the control unit 11 to an analog-to-pulse converter 12, which converts the analog value into an electrical pulse, thereby allowing the value information of the meteorological parameters to be measured to be transmitted.

From there, the pulses to be processed at eight-minute intervals and in a sequence determined by the control unit 11 are supplied by the coding 17, and the encoder 17 is transmitted to the puncher 10 which is triggered by the actuator 9. the required voltage from a transformer supply 16 connected to a 220 V mains or a 2 X 12 V battery.

The pulse signal from the wind speed sensor 5204949 at a frequency proportional to the wind force is supplied to the first wind speed integrator 13, from which at an appropriate time determined by the control unit 11 the integrated wind speed integrator 13 is supplied by encoder 17 and encoder 17 to punch 10 Analogously, the pulse signal from the rain sensor 6 is supplied by the second rain integrator 14 to the encoder 17 and the punch 10. The mechanical signal from the wind direction sensor 7 is supplied to an anemometer for measuring wind direction provided with a mechanical-contact signal converter. and then at a suitable moment for a signal from the control unit 11 to the encoder 17 and the punch 10.

The drive 9 (see FIG. 2) is switched on to measure the meteorological data by the switch unit 8 only for punching the tape 18, then automatically disconnects and remains disconnected until it is reconnected to measure another parameter. Thus, this circuit consumes only small amounts of energy and is very stable.

The drive consists of an electric motor 24 driving the main shaft 27 of the tape puncher 18 to the control unit 11 via a worm gear 25 and a gear 26.

The control unit 11 cyclically connects the sensors 1 to 7 to the analog-pulse transducer 12 and the two signal processing integrators 13, 14, converting the signal to the encoder 17 and the puncher 10 at one minute intervals defined by the control circuit 8 that actuates the drive 9 exactly every minute.

The circuitry 8, shown in detail in FIGS. 3 and 4, is comprised of a clock 19 in which, in order to achieve the time-related objective at one-minute intervals, a second hand having a mirror at its end is mainly used. The light beam emitted by one of the two electric bulbs 22 (the bulbs are doubled in case one bulb burns) is reflected by the mirror 21 and projected onto the photodiode 23, which generates an electrical signal at one-minute intervals which turns on by amplifier 24 drive 9.

The actuator 9 is actuated every minute, each actuation being designed to take one measurement of each of the seven sensors 1 to 7. Every eighth time signal sent to the actuator circuit 8 is induced on the timer 15 to indicate the completed measurement cycle. This information, when sent to the encoder 17, is also punched on the punch tape 18.

Thus, every ninth signal from the control circuit 8 starts a new measurement cycle.

Both identical wind speed and rain integrators 13 are illustrated in detail in Figures 5, 6 and 7, which schematically illustrate the kinematic relationships of the mechanisms of these integrators 13 and 14. They are formed as follows:

The information from the wind speed sensor 5, or analogously from the rain sensor β, is transmitted in the form of an electric pulse to the first closing solenoid 28. The retraction of the first core 29 of this first solenoid 28 corresponds to the downward movement of the single-arm lever 30; the latch 31 is fixedly attached to the lever 30 and this causes the ratchet 32 to rotate by one tooth; the ratchet 32 is fixedly mounted on the shaft 33 together with the two disks 34 and 35 of the first and second tooth clutches.

Rotation of the first ratchet 32 by one tooth is transferred by the first shaft 33 to the first contact hand 36 by means of a clutch whose one disc 34 is mounted loosely on the first shaft 33 and fixed with the first ratchet 32 on the integrator body 37 The first contact hand 36 has two shorting contacts 38 which, when moving in sequence on separate segments 39 of the integrator disc 40, short-circuit the integrator segment 33 and the first ring 41. The electrical pulse transmitted along this path after passing through the encoder 17 is recorded as information on the values read from sensors 5 and 6 during the eight-minute measurement cycle.

When the eight-minute measurement cycle is complete, the wind speed integrator 13 and the rain integrator 14 are reset to their initial position. This is accomplished by the second electromagnet 42 which, by its second core 43, causes the flexible connector 44 to cause the first shaft 33 to disengage the ratchet clutch disks 34, 35. The spring 45, which places the first shaft 33 in its normal position, moves the ratchet disk 32 and the contact hand 36 to the zero position, in which the pin 46 attached to the shaft 33 rests against the support 47 fixed in the integrator body 37. At the same time, the first contact hand 36 together with the first shaft 33 also returns to the initial position.

Giant. 8 and 9 show the timer 15. It is constructed similarly to integrators of wind speed and rain 14. On the base 48 a third electromagnet 49 is mounted, which upon receiving an electrical pulse from the control unit 11 corresponding to the completed eight-minute measuring cycle, pulls the second core 50, which causes the second lever 51 and the second latch 52 firmly attached thereto. the ratchet 53 rotates one tooth. Simultaneously with the second shaft 54, the second contact needle 55 is rotated and its contacts 56 short-circuit the nearest second time meter segment 57 with the ring 58 on the time meter disk 59.

As a result of the short circuit of the nearest circuit, a pulse is transmitted to the encoder 17 and is recorded on the tape 18 by the punch 10.

The timer 59 has 60 segments and as a result can record information from an eight-hour period in a single turn. The eight-hour period is recorded on the tape 18 as a nonperforo207494 tub section and therefore it is possible to clearly and easily find the cycle of measurements made during the eight-hour period.

Multiples of this measurement period can be easily related to measurements with a period of 24 hours, one week, one month, and these time periods are determined in connection with the preparation of data for statistical purposes.

The resistance thermometer 2 for measuring the temperature and the hygrometer 4 are placed in a meteorological box at a height of two meters above the ground. The sensors on the stands, namely the thermoelectric battery 1 and the rain sensor 6, are placed on the same level. The wind speed sensor 5 and the wind direction sensor 7 together with the mechanical-pulsed wind direction signal transducer are mounted on a tubular mast at a height of four to eight meters above the ground. The other devices, i.e., the analog-pulse signal transducer 12, the wind speed and rain 14 integrators, the impulse signal rain 14, the control circuit 8, the drive 9, the punch 10, the control unit 11, the encoder 17, the battery 16 are located in a separate cab from sensors. There is also a thermostatic heater in the cab, which keeps the temperature of the device in cooler seasons. The cabin is also used for storage of punched tape. If it is necessary to transmit the measurement results immediately to the collection station, a remote transmission device may be located in the cab.

The operation of the automatic climatological station together with the replacement of the punched tape, inspection of the work of sensors and other components is basically carried out once a week, but in special cases the station can work unattended for a month.

Claims (6)

1. Automatic climatological station with fully automatic recording of several different selected meteorological parameters and time measurement for reading these parameters on a single punched tape, containing sensors of solar radiation, temperature, humidity, rain and wind speed, anemometer for measuring wind direction in the form of mechanical-contact a signal converter and an analog-pulse signal converter that converts the analog value into an electrical pulse, allowing the device as a contact block to transmit the measured value of the measured meteorological parameter, the station being powered from its own DC power supply plus four sensors transmitting the physical value signal in analog form is connected to the analog-pulse signal converter via the control unit and two sensors transmitting the physical value signal in in the form of an electrical pulse, each directly connected to its respective wind and rain speed integrator, each of which is in turn connected to a control unit and a coding unit, characterized in that its drive (9), tape punch (10) and analogue - the pulse transducer (12) is connected by a common main shaft (27), which in addition has a switching circuit (8) with predetermined time intervals, wherein the analog-pulse transducer (12), wind speed integrator (13), integrator (14) The rain, the timer (15) and the directional anemometer with the wind direction sensor (7) are connected to their common encoder (17), which is connected to the tape punch (10) to transmit the processed information in the programmed code system. Automatic climatic station according to claim 1, characterized in that the closing circuit (8) in the form of a selected clock hand (20) is provided with a mirror (21) at its ends and the edge of the clock face is provided with a photocell (23). located between two bulbs (22), the electrical circuit of the photodiode (23) being connected via an amplifier to the power supply switch of the motor (24) of the drive (9) and to the control unit (11). 3. The automatic climatic station according to claim 1, characterized in that in its drive (9) the electric motor (24) is connected to the main shaft (27) by means of a worm wheel (25) and a gear (26). An automatic climate station according to claim 1, characterized in that in a wind speed integrator (13) and a rain integrator (14) equipped with a first electromagnet (28) and a second electromagnet (42), the coil of the first electromagnet (28) is connected to an electric the wind speed sensor (5) and the rain sensor (6) circuit and the coil of the second electromagnet (42) to the electrical circuit of the control unit (11) for supplying pulses for example in an eight minute cycle, the first core (29) of the first electromagnet (28) connected to a single-arm lever (30) to which the latch (31) of the first ratchet (32) is coupled, the first ratchet (32) is loosely mounted on the first shaft (33) to which the first clutch disc (34) is also loosely attached; wherein the first disc (34) is rigidly coupled to the first ratchet (32) and the second disc (35) is rigidly coupled to the first shaft (33) at which, at the opposite end to the clutch, the first contact needle (36) is fastened rotatably relative to the first multi-segment disc (40), the first contact needle (36) has two short-circuit contacts (38), the first of which is located on the first metal ring (41) of the integrator disc (40) and the second is opposite the mutually insulated segments 39) an integrator arranged around the periphery of the integrator disc (40), the first ring (41) and each of the integrator segments (39) being galvanically connected by a separate circuit to the encoder (17). An automatic climate station according to claim 1, characterized in that in its time meter (15) the coil of the third electromagnet (49) is connected to the control unit (11) and the second core (50) of the third electromagnet (49) is connected to a second single-arm lever (51) to which a second ratchet (52) of the second ratchet (53) mounted on the shaft (54) of the time meter (15) is attached and a second contact handle (55) rotatably relative to the second shaft (54) to the second multi-segment disc (59), the second contact needle (55) has two short-circuiting contacts (56), one of which is located on the other metal ring (58) of the other disc (59) and the other is opposite the mutually insulated segments (57) along the circumference of the second disc (59), the second ring (58) and each of the segments (57) of the time meter (15) are galvanically coupled via a separate circuit to the encoder (17). 6. Automatic climatic station according to claim 5, characterized in that the solenoid coil (49) is connected to the pulse excitation control unit (11) at eight-minute intervals.