NO166984B - PRESSURE REDUCING VALVE. - Google Patents

Abstract

Pressure regulator for controlled supply of gas or liquid with selected pressure to a user stage from a pressure source, the pressure regulator comprising an inlet channel (2) which carries gas or liquid from a pressure source and an outlet channel (3) which leads the gas or liquid to a user site, said channels separated by a spherical valve plug (4) with a seat (5); a lifting pin (10) for the spherical valve plug (4), said lifting pin having an upper part (16) with reduced cross-sectional area and resting on a piston (11) which is manually biased by a spring in a regulating mechanism (12); channels (13) between the outlet channel (3) and the upper side of the piston (11); a balance channel (8) connecting the outlet channel (3) to a cylinder (15) with a balance piston (6) with gaskets (18) for gas or liquid sealing against the cylinder wall, and said balance piston resting on the spherical valve plug.

Description

System for direct magnetic recording of television signals.

The invention relates to a system for direct magnetic recording of the television signal on an elongated recording carrier, comprising an input circuit which is connected to the source of the television signals, an amplifier for these signals, a separator for separating the synchronization pulses from the television signal, a magnetic recording head unit which is fed to the amplified television signal or the video signal without synchronization pulses, without being processed in a high-frequency modulator, and a high-frequency biasing oscillator or the like connected to the recording head for supplying a biasing signal for electrical or magnetic superimposition in the recording head unit.

In normal video recording, a high-frequency premagnetization signal is applied to the television signal either electrically or magnetically, so that the recording takes place in a straight area of the B-H curve for the recording medium, in order to reduce otherwise possible distortion of the television signal during the recording on the recording medium.

In this case, the premagnetization signal is produced

in an electronic oscillator and imprinted on the recording medium independently of the television signal from the television receiver. It has been found that, particularly when using a low frequency bias signal, white and black horizontal stripes often appear on the picture screen on which the recorded or reproduced signal is displayed. Investigations have shown that the production of such disturbing noise strips is due to the difference between the synchronization signal pulses in the processed television signal and the pre-magnetization signal applied to it, and this difference is due to the independence between the way the two signal sources function. It may therefore happen that the leading or trailing edge of a series of synchronizing pulses contained in the television signal is generally subjected to different biasing effects of the biasing signal, even if the biasing signal has an ideal, constant frequency, as will be explained in more detail below, and this leads to an irregular shape of the sync pulses during rendering.

The purpose of the present invention is therefore to provide an improvement of the system for direct magnetic recording using high-frequency premagnetization techniques, so that the recording of irregular premagnetized synchronization signal pulses of the television signal, which otherwise produces disturbing white and black horizontal noise stripes on the picture screen when the television signal is reproduced.

This is achieved according to the invention by an electronic device to influence the high-frequency magnetization oscillator, so that the pre-magnetization signal occurs simultaneously with the synchronization pulses delivered from the synchronization pulse generator.

Further features and advantages of the invention will be apparent from the following description with reference to the drawings. Figure 1 schematically shows a curve for a recorded television signal superimposed with a high-frequency bias signal. Figures 2A and B show on an enlarged scale two examples of the trailing edge of synchronizing pulses with different effects of the biasing signal for different synchronizing pulses of the television signal as a result of phase difference. Figures 3 and 4 show block diagrams for two preferred embodiments of the system according to the invention. Figure 5 shows a block diagram for a third embodiment of

the system according to the invention.

Figure 6 shows a gate circuit for controlling the premagnetization source in the system of Figure 5* Figure 7 schematically shows a fourth embodiment of the system according to the invention. When, as shown in figure 1, a pre-magnetization signal is superimposed on a video signal, the number of repeated frequencies and the degree of pre-magnetization will usually be observed differently, particularly in the area of the leading and trailing edge of a series of synchronization pulses in the video signal. Figure 2 A and B show two different states of the effect of the premagnetization signal as it occurs in the area of the trailing edge of the synchronizing pulses. This different effect is very pronounced with low-frequency biasing signals. In that case, some kind of interference will be formed. On the other hand, when reproducing a recorded television signal in a magnetic video tape recorder or the like for direct recording of direct reproduction, the desired perfect equalization in the reproduced signal cannot practically be achieved if there is a small signal-to-noise ratio and a signal with a wide frequency band. The amplitude of the synchronization pulses in the reproduced television signal is then mainly dependent on the recording state for the trailing or leading edge of each pulse, even after normal equalization in the reproduction system. In other words, the signal transmission quality for the recording system is highly limited, so that when the signals contain high-frequency components, as is the case when recording television signals, the relative speed between the magnetic head and the tape must be increased significantly compared to what is normally used with ordinary audio tape recorders , and this will introduce a corresponding adverse effect on the transmission characteristic for the lower frequencies, which results in a reduced signal-to-noise ratio. For that reason, the above-mentioned insufficient equalization effect will occur and the output signal will have a smaller differentiation effect, which means that with a higher frequency of the reproduced signal, the output signal will generally be larger. ;Particularly if the biasing signal is applied to the television signal in the region of a synchronizing pulse as shown in Figure 2A, the amplitude of the pulse when reproduced will be greater than the desired standard value. The opposite will happen if the biasing signal is applied to the trailing edge of a synchronization pulse in another way, as shown in figure 2B. It can therefore be generally said that if the television signal which is superimposed with a high-frequency biasing signal and recorded magnetically in a direct manner and reproduced by means of a magnetic reproduction head, the synchronizing pulses will have different amplitudes. If a television signal with variable sync pulses is normally subjected to direct current restoration, the video signal will also be subjected to a similar degree of unintended reactions, so that horizontal black and white noise stripes are produced on the television screen. ;In the usual video recording technique, the frequency of the biasing signal is therefore increased significantly, e.g. to more than 10 MHz, in order to avoid the above-mentioned disadvantages, so that the repetition frequency in the area of the trailing edge of each of the synchronization pulses increases and the biasing effect in this area is usually compensated as much as possible. When using a higher frequency of the biasing signal, however, the impedance of the coil in the recording head will be correspondingly greater, so that the energy supplied to the biasing oscillator must be increased to a corresponding degree, which entails a significant loss of energy. Another precaution that is used in conventional recording techniques to avoid the above-mentioned disadvantages is to reduce the strength of the recording current, but thereby necessarily introducing a reduction in the signal-to-noise ratio. ;In Figure 3, the television signal to be recorded is supplied, e.g. from a television receiver, a vidicon camera or a similar signal source to an input terminal 10. The input terminal 10 is connected to a video amplifier 12 which may be of conventional construction and is therefore only shown schematically as "ri block. From a connection point 11, a conductor 13' leads to a synchronization separator 14 which can also be of the usual type and is only shown as a block. The synchronization separator 14 is electrically connected to an input of a phase discriminator 15, the output of which is connected to the input, of the high frequency biasing oscillator 16 which is of conventional construction. The phase discriminator 15 is also of ordinary construction. The pre-magnetization oscillator 16 is connected at a connection point 17 to the recording head l8a with a use gap l8b and is preferably of the stationary type and is in sliding contact with an elongated magnetic recording carrier 20 in the form of magnetic tape. Tape spools and the necessary drive mechanism for the tape are not shown in the drawing for the sake of simplicity. From another output in the biasing oscillator 16, a conductor 21 leads to a frequency divider 19 which divides the biasing frequency by a certain number, e.g. 200 so that a reference signal is obtained with a frequency of 15>75 Hz calculated for an image with 525 lines which corresponds to the synchronization signals in the television signal which is supplied to the input terminal 10. The system for direct magnetic recording according to the invention works in the following way: If a television signal is applied to the input terminal 10, this will simultaneously be fed through the conductors 13 and 13' to the video amplifier 12 and the synchronization separator 14. In the synchronization separator 14, the synchronization signals will be separated from the television signal and fed to the phase discriminator 15, which is also fed a reference signal from the frequency divider 19. From the output of the phase discriminator 15, the premagnetization oscillator is fed A control signal. as a function of the phase difference between the synchronization signal and the reference signal, thereby bringing the premagnetization signal from the oscillator 16 in accordance with the horizontal synchronization pulses in the television signal. The premagnetization signal which is controlled in this way is superimposed through the conductor 23 at 17 the amplified television signal from the output of the video amplifier 12 through the conductor 22, and the combined signal is supplied through the conductor 24 to the coil l8a in the magnetic recording head l8 whose use slot l8b with e.g. a length of l^u, and which cooperates with a magnetic tape 20 which runs at a speed of 114 cm per second. The tape's dimensions can be of the usual standard for home use. In the television signal modified and illustrated in this way, the relative phase relationship between the synchronizing pulses and the biasing signal will be maintained at a constant, each synchronizing pulse being processed by the biasing signal to a similar effect. The series of modulated television signals obtained in this way can easily be imagined as a series of video signals which are interrupted at regular intervals by a number of separate synchronization pulses, an example of which is shown in figure 2A or 2B. instead of the amplified television signal, an amplified video signal, which is formed by separating synchronization pulses from the television signal, can be fed through the conductor 22 to the coil l8a with the same result by a minor modification of the amplifier 12. In the embodiment in Figure 4, the reference numerals 10 -24 same application as in figure 3" The output signal from the synchronization separator 14 is fed through a conductor 44 to a frequency multiplier 25 which can be of conventional construction and which multiplies the input signal so that e.g. receives a high-frequency premagnetization signal of 3>15 MHz. The pre-magnetization signal thus produced is supplied from the output of the multiplier 25 through the conductor 26 to the connection point 17 where it is superimposed on the amplified video signal from the amplifier 12 through the conductor 22 in the same way as in Figure 3. The combined signal is recorded on the magnetic tape 20 using of the magnetic recording head 18. It is clear from the foregoing that also in the embodiment in Figure 4 there will be a specific phase relationship between the synchronization pulses and the premagnetization signal. In the embodiment shown in Figures 5, 6 and 7, the premagnetization signal is generally synchronized with the synchronization pulses in such a way that the premagnetization signal is balanced or weakened significantly in the area of the synchronization pulses. The components 10,11, 13) 13' and 14 correspond to the components in the previous embodiments. 27 denotes a delay circuit for the received television signal coming from the terminal 10 through the conductor 13. During operation, the television signal is supplied from the terminal 10 through the connection point 11 and the conductor 13' the synchronization separator ^ 14' and from this only the synchronization pulses are taken as before, and these are supplied to a. differentiation circuit 28. The differentiated synchronization pulses are supplied to a monostable multivibrator 29 for controlling this. The time constant of the multivibrator is chosen equal to the sum of the duration of a synchronizing pulse plus the adjacent extinguishing period. It is clear that a series of signal pulses can be derived from the output of the multivibrator 29 if a continuous television signal is supplied to the terminal 10, each of the output pulses extending over the blanking period. These pulses are supplied to a gate circuit 30 which receives the output signal 33 from a high-frequency biasing oscillator Jl through the conductor 32'. The gate circuit 30 is controlled by the output signal from the monostable multivibrator 29, so that the emitted output signal 34 has correspondingly evenly distributed interruptions or significantly attenuated parts, and these extend over the blanking periods in the television signal. On the other hand, the television signal is supplied to the delay circuit 27 with a delay time of at least 1.3 msec. or 0.02 H ; (H is the period from the beginning of the scan of one line to the beginning of the scan of the next line), such that the length of the leading edge of the synchronization pulse, and the output of the delay circuit 27 is fed to the amplifier 4° through a conductor 39. The thus delayed and amplified television signal is mixed at the connection point 36 with the modified premagnetization signal delivered from the gate circuit ^ 0, and this signal has either less energy or a lower voltage level in each blanking period as mentioned above. The combination signal 41 is supplied to the winding 37a in the recording head 37* As can be seen, the recording signal in this case lacks the superimposed premagnetization signal in each extinguishing period and comprises a synchronization pulse with a duration of 5.1 msec. or 0.08 H in connection with a front and a rear flank with a duration of 3>8 msec. or 0.06 H. It will therefore appear from the foregoing that by using the modified recording signal, the major disadvantage of ordinary recording and reproduction due to different influences of the synchronization pulses will be eliminated.

Figure 6 shows a circuit for modifying the premagnetization signal in the above-mentioned manner.

Here the signal from the premagnetization oscillator 31

by means of a coupling capacitor 42 and a resistor 43 supplied to the control grid in an output tube 46, which control grid is decoupled to ground by means of a resistor 48. The cathode of the tube 46 is grounded, while the anode pl through a swing circuit consisting of the coil 49 °§ the capacitor 15 is connected to a voltage source B. The anode pl is also connected through a capacitor 52 to one end of the winding 37a °S the connection point 51 corresponds to the connection point 36 in Figure 5» °g the other end of the winding 37a is connected to ground.

The input terminal 53 which is connected between the blocks -28 and 29 in Figure 5 is decoupled to ground through the resistor 55 °g through a capacitor 56 with the base in a transistor 58, and this base is decoupled to ground by means of a resistor 59- Transistor's 58 emitter is also connected to earth, while its collector is connected to the control grid eg in the tube åfi.

Each output pulse from the multivibrator 29 is supplied through the input

the terminal 53 °S the capacitor 56 to the base-emitter of the transistor 58

circuit. During the period in which the base-emitter circuit to-

signal is passed, the collector-emitter path of the transistor will be conductive and the output signal from the biasing oscillator 31 will be grounded through the transistor. During this period, no signal will be supplied to the control grid eg in the tube åfi and the recording head 37 will have no pre-magnetizing flux to the use slot 37°• The recorded television

signal on the band using the use slot 37° is therefore not

magnetized at evenly spaced intervals and during each quench period.

Figure 7 shows a slightly modified embodiment of Figure 6.

Here, the components 20, 31, 37, 37a, 37b, 42, 45, 53, 54, 55, 5<6,> 57, 58 and 59 are the same as in figure 6, while the resistor 43 has been moved to the collector-emitter path in the transistor 58 and given the reference 43'•

In operation, the signal is supplied from the biasing oscillator

31 through the capacitor 42 to the winding 37a in the recording head.

At the same time, periodic pulses are supplied from the multivibrator 29

and these cover each blanking period in the television signal, and these pulses are supplied to the base-emitter path in the transistor 58 so that this means

early becomes conductive, and the premagnetization signal from the oscillator 31

is short-circuited to earth at point 45 vecl using the resistor 43' °S col-

the collector-emitter path in the transistor 58. At this moment, therefore, the pre-magnetization signal from the oscillator 31 will not be supplied to

the drawing head 37- It is clear from the foregoing that the television signal that is applied to the recording head does not contain premagnetization sig-

nal during each extinguishing period and the resulting signal is that indicated by 41 Pa Figure 5>°g on an enlarged scale in Figure IB.

The recording head 37 is supplied with the modified biasing signal

which is superimposed on the television signal to be recorded. A special pre-magnetization head can be arranged so that this is only fed to the pre-magnetization signal and physically mainly opposite to the usual endorsement head, as this is commonly known from the system with a cross-

walking field. Instead of periodically interrupting the premagnetization sig-

nal, this can be given a significant periodic reduction. It is clear that the system according to the invention can also be used for recording color television signals.

Claims (3)

1. System for direct magnetic recording of television signals on an elongated recording medium, comprising an input circuit connected to the source of the television signals, an amplifier for these signals, a separator for separating the synchronizing pulses from the television signal, a magnetic recording head unit which is supplied to the amplified television signal or the video signal without synchronizing pulses, without being processed in a high-frequency modulator, and a high-frequency biasing oscillator or the like connected to the recording head for supplying a biasing signal for electrical or magnetic superimposition in the recording head unit, characterized by an electronic device for influencing the high-frequency premagnetization oscillator, so that the premagnetization signal occurs simultaneously with the synchronization pulses delivered from the synchronization pulse separator. 2. System according to claim 1, characterized in that the recording head unit consists of a single recording head. 3. System according to claim 1, characterized in that the electronic device comprises a frequency divider which is connected to the output of the biasing oscillator for dividing the frequency of the biasing signal by a specific whole number, so that a reference signal is formed, and a phase discriminator for comparing the output signal from the separator and the reference signal to derive a control signal that affects the bias oscillator. 4- System according to claim 1, characterized in that the biasing oscillator is a frequency multiplier which is influenced by the synchronization pulses to give the biasing signal a frequency that is a specific multiple of the frequency of the synchronization pulses.