KR19990038902A - Power Ground Circuit - Google Patents

Abstract

The present invention derives the neutral point equipotential to the earth directly from the power supply by using the ground line formed on the converter due to the transformer secondary coil neutral point grounding to offset the high potential formed on the power supply. The present invention relates to a power grounding circuit that can be used as a grounding source for removing electromagnetic waves (electric field) without the need for grounding and additional lines.

In order to realize this, in the present invention, the terminals of the variable resistor (Variohm) fixed resistor (R) having a capacity suitable for both ends of the power supply lines (A, B) are connected to the load, and the neutral point on the same load line is caused by the offset action between the power supply potential polarities. (Definition: The point where the polarity is canceled mutually on the converter or the load line, so that the potential difference with the earth is 0 volts or close to 0 volts) is derived, and the neutral point derived from the fixed resistor is moved by moving the sliding resistor M of the variable resistor. If G) is found and matched correctly, the sliding terminal of the variable resistor is formed by forming the sliding terminal (M), the derived neutral point (G), and the grounding line connected electrically to the inlet line and the transformer ground point. It can be used as a grounding source required by the present invention.

However, if the ground potential of both power lines (A, B) is both positive (+) and more than a few volts, it is impossible to cancel each other due to the lack of negative potential. In the present invention, a potential change coil (L) is inserted in parallel and in parallel between the power supply line and the fixed resistor terminal of the variable resistor in order to change the potential of the power supply line (neutralization induction voltage). By generating the neutral point within the fixed resistance.

The discharge lamp principle was used to find the exact neutral point.When the contact plate (D) is touched, as shown in the representative drawing, an electric field flowing to the human body flows, and the discharge lamp (T) moves while the slide (M) is moved. By gathering the brightness of the device so that the potential change can be read, the point with the lowest potential, that is, the exact ground point, is found.

Therefore, as described above, the ground potential is near zero volts in the power source having any earth potential characteristics through the variable resistor, the coil, and the discharge tube, so that the ground point is derived. A ground source can be obtained directly from the power supply, which is not enough to use as a support.

Due to the present invention, in addition to such a functional effect, in terms of economics, the costly grounding work is unnecessary or simplified, and thus the human cost can be indispensable.

Description

Power Ground Circuit

The present invention relates to a power supply ground circuit for removing electromagnetic waves generated in home appliances.

Most home appliances that use AC power inevitably radiate unnecessary electromagnetic waves from extremely low frequency induced from the power source to ultra-high frequency generated from the parts of the device, thereby causing electromagnetic interference not only to the device itself but also to external devices. It is known to have a bad effect. In order to cancel the electric field of the electromagnetic wave, it is most effective to shield the electromagnetic wave source with a conductor and earth it.

However, grounding requires a lot of manpower and money due to the complicated work, such as the work required to bury the Earth Bar or Earth Plate on the ground and connect the ground wire to the ground. Some customers use water pipes or heating pipes as grounding sources, but it is also not only a hassle to extend the wires to the ground, but also aesthetically not good.

The present invention by using a power grounding circuit, rather than the conventional grounding method as described above to find the grounding point directly from the commercial power source and use it as a grounding source by eliminating the need for a separate grounding work and additional grounding line Electric field) and a weak leakage current, etc., to have a function as a grounding source sufficient to earth.

1 is a circuit diagram of the present invention

2 is a partial view of the ground circuit (potential change characteristics according to the power supply change)

3 is a principle diagram of power grounding (potential adjustment principle by coil)

The configuration and operation principle will be described in detail with reference to the accompanying drawings. In FIG. 2, a ground voltage due to mixing of a converter or a lightning strike is applied to the neutral point G of the secondary coil L ₁ of the terminal transformer for outputting a voltage to the customer. (Earth potential difference with earth) Earth is necessarily grounded for the purpose of restraining the rise and stabilizing the converter in case of ground accident, and the grounding point (E) is connected to the power outlet of the customer through the inlet path without disconnection. The enemy is connected. In other words, the ground line is formed on the power line. However, a high earth potential of more than a few volts induced through the transformer secondary coil (L ₁ ) is formed in the power supply line, so it is not possible to connect any one of the power supply lines directly to the ground source.

Therefore, if by any means it is possible to induce a high earth potential applied to the power supply line to zero volts or less without affecting the supply voltage, and the electrical connection to the ground point of the transformer can be maintained without interruption If so, the grounding condition as a grounding source is satisfied, and of course, the grounding current can flow to the grounding point E of the transformer, so that it can be used as a grounding source.

In addition, as a condition to be satisfied, as shown in Fig. 2, even if the power supply voltage is the same voltage of 220 volts, it is applied to the power supply line for each customer according to the magnitude and polarity of the earth potential of the voltage output point in the secondary coil of the transformer. The earth potential will be different and also slightly different depending on the conditions of the incoming path. In this way, the grounding point can be found only when the grounding point can be found even under different earth potential conditions.

Therefore, in the present invention, a variable resistor and a coil were used as a method for satisfying all the above grounding conditions. As is well known, the variable resistor can use a fixed resistor as a load and control the current by changing the resistance value, and the slide can change the contact point while maintaining the contactability, that is, the contact point continuous variable characteristic (the contact state is maintained). Characteristic), first, load is applied to the power supply using the fixed resistor (R) of the variable resistor to derive the ground point of neutral point (G), that is, earth potential becomes 0 volt on the load line, and the derived ground point (G) If exactly match and match using the continuous variable point of the contact point of the sliding element (M), the derived power ground point (G 'of Figure 2) and the transformer ground point (E) is a complete electrical connection between each other. In addition, it is possible to adjust the potential of the power supply using the electromagnetic induction characteristic of the coil, so that the neutral point outside the load resistance can be induced into the resistance.

Referring to the operation principle in more detail with reference to Figure 2, Figure 2 illustrates the change in the ground potential according to the withdrawal point when outputting a voltage from the transformer secondary coil (L ₁ ) and the coil (L) in a power source having a variety of ground potential And a partial circuit diagram for explaining the principle of deriving the ground point G 'through the variable resistors R and M. When the symbol is described, the coil L ₁ is a transformer secondary coil and points 1, 2, 3, and 3 5, is the tap point for drawing the output voltage, and point G is the neutral point, which is grounded, and is connected to the coil L by conductors J and K. Coil L is a potential compensation coil. Points 8 and 9 are tap points for potential compensation, and the connection is interrupted by a changeover switch (S _{2 in} FIG. 1). Points 6 and 9 and points 7 and 8 are simultaneously connected. Points 2 and 8 are always connected when points 1 and 6 are connected, and points 2 and 7 are simultaneously connected when points 1 and 9 are connected. The coil is connected to R by wires W and Z, where R is the fixed resistance of the variable resistor and M is the sliding (variable terminal). The voltage V between points 1 and 2 is 220 volts, the voltage V ₁ between points 6 and 7 is 260 volts, the voltage at V and V ₂ is the same, and the voltage at V ₁ and V ₃ is the same. As shown in Figure 2, even if the power supply voltage is the same 220 volts, the ground potential on the power supply line varies by about ± 240 volts depending on the method of outputting the voltage from the secondary coil, if the transformer secondary coil L ₁ If the voltage is drawn from the points 1 and 2 of the ground potential, the ground potential of the points 1 and 2 is 110 volts, and the polarity is opposite (because the transformer neutral point is grounded and the voltage is taken from both ends of the coil). Just by connecting to the fixed resistor of the potentiometer (points 1 and 10, and connecting points 2 and 11), the potentials cancel each other out, resulting in a neutral without polarity within the resistor. That is, in the case of a power source having a ground voltage of 0 volts or more and a polarity opposite to each other, a ground point can be easily derived from the load resistor through a variable resistor without a potential compensation coil. If the ground voltage is the same and the polarities of the two power line potentials are the same, the ground point will deviate from the load line of the potentiometer and, of course, the ground point will not be obtained from the power supply. For example, in the case of outputting power at points 3 and 5 in Fig. 2, even if the power supply voltage is the same 220 volts, the earth potential of point 3 is +20 volts, the earth potential of point 5 is +240 volts. Since the potential in the load resistor is not completely canceled (neutralized), the minimum potential obtained by manipulating the slider in the load resistance is +120 volts, which is 20 volts higher than the earth potential, thus functioning as a ground point. You will not be able to. Grounding is to minimize the equipotentialization or potential difference by electrically connecting the earth or a grounding conductor higher than the earth, so to achieve the earthing effect, a grounding point equal to earth, or ground voltage close to 0 volts or 0 volts, is required. Since the potential in the resistor is high and the ground point is out of the load resistance, the ground point close to zero volts cannot be found in the load resistance only by operating the slider M. Thus, the current (I ₂₎ connected to the coil L ₂ has a taepjeom When this voltage is a voltage to occur between the mutual electromagnetic induction of a coil points 12 and the point 14 of action of the coil inductance polarity that is flowing, as shown in Figure 3 Since the direction is opposite to the current (I ₁ ) flowing in the load resistance, the potential drop is brought by the magnitude of the voltage generated by canceling each other in the load resistance, and the neutral point is pushed into the fixed resistance (R), which eventually leaves the load resistance. The ground point is brought into the load resistance, and thus the grounding point can be derived by moving the slider.

If the ground voltage of the power line is the same and the polarity is the same at any customer, the grounding point is the same, so the variable resistor can easily derive the grounding point using fixed resistor, condenser, coil, etc. The ground potential on the power line must be different for each customer due to the different draw points for outputting the voltage from the transformer for each power source, the neutral point shift due to the transformer manufacturing error, the characteristic difference of the induction coil, and the characteristic difference between the inlet and the indoor wiring line. Therefore, as in the present invention, the method of finding the ground point using the slidability (contact continuous variable characteristic) of the variable resistor and the magnetic induction characteristic of the coil is not only simple and accurate, but also once adjusted, the ground point is changed unless the power equipment is changed. This permanent retention eliminates the need for frequent ground point adjustments It is not affected by power outages, and because the circuit is simple, there will be no breakdown and practicality will be great.

In addition, in the case of a power supply drawn with the neutral point of the transformer (G in FIG. 2) as one line, it is easy to think that the ground potential of 0 volts will be displayed in the customer's outlet as the power line is directly connected to the ground point without going through the coil. The earth potential of several volts is generated in the power line due to the neutral point shift of the transformer coil and the mutual induction action of the coil on the inlet path. Therefore, the potential adjusting coil L is necessary even in this case. For reference, if the length (winding) of the potential adjustment coil is changed, the width of potential change will change in proportion to it, so adjust the coil length appropriately if necessary.In the case of domestic power supply, if you can induce a potential change of about 40 volts, The most efficient ground line can be formed.

As described above, the potential difference of several tens of volts can be overcome, and therefore, the ground point can be derived from a power source having any potential characteristic, and the fixed resistance of the variable resistor (load By properly changing the resistance value, it is possible to flow the required ground current with the minimum power consumption, and if only the radiating radiator of the variable resistor is set up, the function as a definite grounding device that can flow even a substantial ground current will be fully utilized.

To accurately identify the grounding point, the principle of the discharge tube (definition: connecting one terminal of the discharge tube to the ground or a higher conductor than the ground and the other terminal to a ground or a lower conductor such as a conductor or a human body connected to it) By using the principle of a device that emits light while a high-charge electric charge flows to a low electric potential), it is possible to simply find the point where the potential difference with the ground is the lowest. Specifically, as shown in Figure 1 while the contact plate (D) in contact with one hand while the other hand slowly moving the slide (M) of the variable resistor from side to side while the lowest point of the light of the discharge lamp (T) If is found, the point becomes the ground point. Due to the nature of the discharge tube, there is a limit to identifying the exact ground point at low potential. Therefore, if you want to find a more accurate ground point, you can do so through a digital tester or a separate simple measuring device.

For reference, as a result of the present inventors practicing the invention, if the resistance value of the fixed resistor (R) is about 120kΩ and the coil (L) has a passing current of about 2mA, the electromagnetic wave emitted from the general home appliance is eliminated. This value is considered to be sufficient, and the grounding resistance is changed by increasing or decreasing the load resistance value as necessary. Therefore, the grounding force (grounding effect) is increased or decreased.A lowering the load resistance value increases the grounding force, but the power consumption and heat generation amount are increased. As it increases, appropriate heat dissipation measures are needed.

1. By saving ground point directly from the power source and using it as a grounding source, without saving earth ground work for the purpose of electromagnetic wave removal, it can save huge human and material cost due to grounding work.

2. It consumes only a few milliamperes of low power and functions as a grounding source sufficient to dissipate electromagnetic induction currents and weak leakage currents.

3. It is possible to derive the accurate ground point from any power supply with any potential characteristics.

4. Because the circuit is simple, it does not take up much installation space, and the manufacturing cost is low

5. There is no malfunction and the grounding point is permanently preserved by one adjustment.

6. It can be used as a grounding source for grounding type security devices used in computer monitors and other home appliances that require grounding.

7. Computers and monitors, as well as TVs, rice bowls, refrigerators, cookers and other electronic devices that are placed in a state of constant power supply or are in close contact with the human body, may be discharged from the body by incorporating the circuits and devices in the body. The scope and effect of the application will be broad, such as being able to be freed simply and completely from the harm caused by electromagnetic waves.

Claims (4)

1, A neutral point (G), or ground point, is derived at an arbitrary point of the fixed resistor by canceling the connection potential of the fixed resistor (R) of the variable resistor (Variohm) to the load at both ends of the power line. By moving the slide (M) of the variable resistor exactly to the ground point (G) derived, the ground line (E) connected between the transformer ground point (E), the variable resistor neutral point (G) and the sliding terminal (M) is Forming, In the case of a power source with a high earth potential (+ potential) whose neutral point cannot be derived within the variable resistor fixed resistance, As shown in FIG. 1, the coil L is connected to the power supplies A and B in parallel and the fixed resistor R is connected in series, thereby changing the potential by using the magnetic induction phenomenon of the coil L, thereby fixing the fixed resistance. The neutral point (ground point) that has been deviated is induced to be derived into a fixed resistance Through the touch plate (D) and the discharge lamp (T) to identify the optimum ground point, A power grounding circuit for removing a commonly known electromagnetic wave (electric field), designed to prevent electric shock and overdischarge by inserting a fuse F between the derived power grounding terminal and the grounded object (FIG. 1).