Protecting the socket for the cable of the metal detector coil. Twisted Pair Coil for Metal Detector Manufacture of Individual Parts

The kit is a set of parts for assembling a universal plastic sensor housing (search coil) for the KOSHCHEY-5I (RI8042) metal detector.
Included with the case are a bracket for mounting it on the metal detector rod.
The housing design is quite versatile and allows you to make sensors for almost all other types of metal detectors.

Below is an article about the manufacture of a basket sensor based on this case.

Characteristics:
• Body material: Plastic;
• Case color: Black;
• Hardware material: Plastic;
• Operating temperature range: -10...+50 degrees Celsius;
• Operating atmospheric pressure range: 710...+800 mm Hg. Art.;
• Relative humidity: Up to 95% (at +25 degrees Celsius);
• Packing: OEM;
• Device dimensions: 200 x 200 x 80 mm;
• Total weight of the set: 180 g.

Contents of delivery:
• Plastic housing (two halves);
• Arm for fastening on a bar;
• Pressure seal PG-7;
• Rod bolt with nut (plastic): 1 set.

Click on the picture to enlarge
(navigation through the pictures is carried out by the arrows on the keyboard)

Components for assembling a pulsed microprocessor-based metal detector KOSHCHEY-5I (RI8042):

KVP basket sensor ("twisted pair")
for metal detector Koschey-5I

The winding of the basket sensor is created in the following sequence:
•1. A piece of cable 2.5 m long is cut off;
•2. We make two notes with a marker:
•2.1. 1st at a distance of 10 cm from one end;
•2.2. 2nd at a distance of 67 cm from the same end (or 57 cm from the first);
•3. Then we make a loop of the first turn of the cable, combining the two cable marks indicated above, as shown in the photo.

•4. Then we begin to thread the free long end of the cable into the loop formed, wrapping the second turn of the cable around the first one. For one turn of the coil of the future sensor coil, it is necessary to make 4 ... 5 wraps, that is, thread the free end of the cable 4 ... 5 times through the ring of the winding being created. Below is the first winding with the second turn of the first turn.

When winding all 4 turns, it is necessary to ensure that the cable is laid, strictly repeating the period of wrapping the previous turns. In this case, the final "steering wheel" of the resulting winding will be compact, dense and neat, as shown in the photo.

•5. The ends of the cable are fixed with electrical tape and bent inside the winding.
•6. The cable ends are shortened to a free length of 6 cm.
•7. At a length of 3.5 cm from the ends of the cable, the outer sheath is removed. This can be done, for example, with nail scissors.
With any method, the main thing is not to damage the internal conductors and their insulation!
•8. Then, in a free section, each twisted pair is untwisted to eventually get 8 pieces of individual wires for desoldering, as shown in the photo.

•9. The ends of all wires are stripped to a length of about 5 mm and tinned.
•10. Then the ends of the wires are unsoldered.
Seven wires from one end of the cable are connected to seven wires from the other end of the cable. The remaining two wires will be the winding leads.
Wire insulation has four designation colors - orange (O), green (G), brown (K), blue (D).
In each twisted pair of two wires, one has a solid color of the four specified colors, and the other has some combination of these colors with white.
The combination with white color will be designated as OB, ST, KB and GB, respectively.
The table explains how the ends of the cable wires are connected to create a winding of 32 turns, and the photo shows how it looks in kind.

	wires end #1		wires end #2
			O	Conclusion No. 2 of the winding
	O	Connect with each other	ABOUT
	ABOUT	Connect with each other	W
	W	Connect with each other	Z B
	Z B	Connect with each other	To
	To	Connect with each other	K B
	K B	Connect with each other	G
	G	Connect with each other	G B
Conclusion No. 1 of the winding	G B

•11. It is most convenient to insulate the places where the wires are soldered with pieces of a thin heat-shrink tube, as shown in the photo. The tube is heated by a mounting hair dryer or simply over the flame of a candle or lighter, after which it tightly fits the place of soldering and is firmly held on it.

Let's show this with an example. For comparison, below are the plots observed on the oscilloscope screen for several options for connecting it to the sensor winding:

1 - connection to the entire winding of the sensor:

• Vertical sensitivity: 50 mV/div • Oscillation period: 1 µs 2 - connection to the tap from 3/8 of the total number of turns, counting from the common bus: • Vertical sensitivity: 20 mV/div • Horizontal sensitivity: 0.5 µs/div • Oscillation period: 0.75 µs 3 - connection to a tap from 1/8 of the total number of turns, counting from a common bus: • Vertical sensitivity: 10 mV/div • Horizontal sensitivity: 0.5 µs/div • Oscillation period: 0.72 µs Let's dwell on this in more detail: The type of cable for the pulse metal detector sensor is not very critical. The cable must be multi-core, flexible, to avoid kinks of conductive cores during long-term operation. The cross section of the cable must be such that its ohmic resistance is much less than the ohmic resistance of the sensor winding (see above). This means that the cross section of each core must be at least 0.15 mm 2 . However, in practice much more is chosen, for reasons of strength, so that the total cable thickness is about 6 ... 7 mm. We used a multicore electrical cable brand PVS 2x0.75. This is an inexpensive, affordable cable, the only drawback of which is its rigidity and fragility in severe frosts. At positive temperatures, there are no problems with the operation of such a cable. •12. We cut off a piece of cable 1.2 m long and strip the ends to a length of 1.5 cm and 3 cm, as shown in the photo. The end with long leads is soldered in the sensor housing, the end with short leads is soldered in the connector. At the moment, we use microphone connectors of the XLRmini type for 5 pins in our products. Such connectors are also used in most metal detectors from other manufacturers. An identifying resistor with a nominal value of 30 kOhm is also installed in the cable part of the connector. The wiring diagram of the connector is explained below. The appearance of the XLRmini connector after its desoldering and after its final assembly is shown in the photo. Before putting on the metal casing, the resistor and connector contacts are insulated with adhesive tape or heat shrink tubing to prevent their contact with the casing. •13. The second end of the cable is then threaded in series through: * Spring shank cable gland; * gland gland; * Case of pressure seal; * Sensor bracket; * Pressure seal nut. •14. The gland housing with the cable passed through it is screwed to the bracket with a nut. •15. The nut is tightened and fixed from turning in the bracket with hot glue. •16. The spring shank is screwed onto the cable gland body, but not tightened, so that the cable can move in the cable gland. •17. Then the end of the cable is passed into a hole 6 mm in diameter drilled in advance for it in the upper half of the sensor housing. •18. Self-tapping screws made of non-magnetic stainless steel measuring M2.9x16 mm are screwed into four pre-drilled holes with a diameter of 3 mm, with which the sensor bracket is attached, and tightened. •19. After installing the bracket, it is necessary to adjust the length of the end of the cable coming out of the housing half. It is necessary that the uncut part of the cable with the sheath protrude no more than 1 mm. •20. After adjusting the length of the outgoing cable, it is fixed by tightening the spring shank of the cable gland. •21. Then the sensor winding is fixed in the upper half of the housing (on which the bracket with the cable is installed). For this, hot-melt adhesive is also used, which is enough to apply in two places of the circle under the winding. It also insulates the ends of the soldered wires of the twisted pair, which, for convenience, are compressed into a bundle using a heat shrink tube. •22. Finally, the winding leads and cable ends are connected by soldering. The soldering is arbitrary. The orange twisted-pair wire can be soldered to the blue wire of the cable, and the blue-white twisted-pair wire can be soldered to the brown wire of the cable, or vice versa. As a result, we get the following view: •23. It remains only to fill the soldering points with hot glue, as well as the places where the wires exit the twisted pair cable, to prevent possible water penetration there. The place where the cable exits from the sensor bracket is also sealed. To lay the cable wires, do not forget to cut two passages in the inner annular stiffener with wire cutters. The final internal view of the sensor is shown in the photo: Now let's take a look at the bottom half of the sensor. •24. It is also necessary to drill 4 through holes in it for self-tapping screws made of non-magnetic stainless steel measuring M2.9x16 mm. Holes are drilled in barrels (cylinders) located closer to the edge of the sensor body. •25. Outside, it is necessary to apply a countersink to these holes, that is, to make a small cone-shaped recess with a large-diameter drill so that later the countersunk head of the self-tapping screw fits into this recess. Countersinking should only be done by hand, preferably with a drill with a diameter of at least 10 mm and with very little pressure. Trying to do it with a drill in a fraction of a second ends up with a huge through hole...J/L. •26. After preparing the lower half of the sensor housing, both halves are combined. If at the same time it turns out that the “steering wheel” of the winding sticks out a little and interferes with the free alignment of the body halves, then it can be molded by slightly (or even not at all slightly) “biting” with pliers around the entire circumference. The twisted pair cable is malleable and easily holds its shape. •27. After that, both halves of the body are screwed together with self-tapping screws. Assembly completed! After assembly, we connect the sensor to the Koschey-5I metal detector and check its operation. As an option, it is possible to connect the body halves with glue. To do this, you can use any glue for gluing plastics. Or make it yourself by dissolving pieces or sawdust of plastic in dichloroethane. This will require a tablespoon of sawdust and 25 ml dichloroethane (sold separately) . With regular shaking, it takes about a day to dissolve. ATTENTION! Dichloroethane should be handled under a fume hood or outdoors due to its toxicity. Conclusion In laboratory tests, the following parameters were obtained: • Winding inductance: 387 uH; • Interturn capacitance: 34 pF; • Winding resistance: 2 Ohm; • Detection range of a coin with a face value of 5 kopecks: Up to 28 cm*. *- The maximum possible value is indicated at the minimum possible indication threshold. The range may be shorter in the presence of industrial interference and the shielding effect of reinforced concrete reinforcement in the conditions of a city apartment, as well as in case of non-optimal target orientation. For example, the metal detector feels the same coin well if its plane is parallel to the sensor plane. But if you turn the coin 90 degrees (edge ​​to the sensor) and bring it strictly along the axis, the coin will become invisible! This is NOT The disadvantage of our particular metal detector is a property of all pulsed metal detectors with a static mode of operation. Thus, an inexpensive, technologically advanced and easy-to-replicate basket sensor design has been proposed. It is no more difficult to manufacture than a traditional wrap wire sensor, but has higher sensitivity. Compared to the classic basket sensor, the sensor with a twisted pair winding loses a little in sensitivity, which is most likely due to the higher ohmic resistance of the winding. In addition, we hope that the proposed design of the sensor is better protected from the harmful effects of moisture, which, as it sometimes happens, can penetrate inside the sensor housing. In this article, we tried to describe in great detail the stages of its manufacture and we hope that this design will become popular :-)

Alternative sensors for a metal detector

Koschei-18M (VM8043)

Part 6. New Concentric Sensor

Despite the fact that we have already developed and published several alternative sensor designs for this metal detector, concentric “ring” type sensors are still in the greatest demand. They are ergonomic, versatile, produced by many manufacturers. However, plastic cases, which are described and which were previously completed with our kits, unfortunately, are discontinued due to reasons beyond our control. And the developed ones turned out to be “too tough” for not all do-it-yourselfers because of the troublesome “ fiberglass-foam" technology. However, available for sale new plastic cases with a diameter of 200mm. They are quite suitable for sensors of induction metal detectors. True, pouring a precision system of coils of such sensors directly into this housing is somewhat problematic. Therefore, we have developed a special casting mold, manufactured using blister technology. Serial production of such forms has now been mastered.

It is worth noting that the winding wires must be new with perfect insulation. Only copper winding wires can be used. It is unacceptable to use used wire, extracted from the windings of electrical devices - as a rule, it has microcracks that can lead to interturn short circuits, which will spoil the result of all painstaking work.

First, we take a casting mold and put strips of fiberglass or ordinary fabric (for reinforcement) into the radial “knitting needles” of the recesses. We lay our coils on top. Before laying the knots of the tightening threads, we unfold so that they are at the bottom. This will lift the coils and allow the resin to flow easily under them.

Next, we connect the coils to the cable according to the diagram. Particular attention should be paid to the phasing of the coils when soldering the cable. The transmitting and compensating coils must be turned on in opposite directions. For ease of perception, the diagram conventionally shows the beginnings and ends of all coils in the form of leads coming out of the coils in a certain direction. This is exactly how you need to orient and solder the ends of "real coils". The figure below shows how to connect the sensor using a “thick” S - VHS cable Belsis BW 7809 PL . Such a cable gives a slightly higher consumption of the device than when using AWM 2919 (thick VGA - double-shielded cable used in computer monitors and plasma displays) or LIYCY-CY (installation low-current cable with double shielding). However BW 7809PL much easier to desolder.

We fix the conclusions of the coils with the help of a small cylinder of plasticine. In addition to fixing the leads, it plays another important technological role - in the future, it forms the places where the wires exit from the casting mass. To do this, in the blister form there is a small cylindrical recess, which should tightly fill the lower end of the plasticine cylinder. The inputs of the winding wires into the cylinder must be located at the level of the horizontal surface of the blister-shaped plastic, and the outputs in the direction of the cable soldering should be above the level of the epoxy resin pouring.

Now we proceed to the preliminary balancing of the sensor. To do this, place the sensor away from metal objects and turn on the “Path Calibration” service mode. Details of entering this mode are described. First, we need to turn on the operating frequency of 7 kHz, Set Gain 1 and a phase shift in the region of 150-160 degrees. The winding data of the coils is chosen in such a way that at first the compensating coil creates a slight overcompensation. In this case, the scale X and Y deviate to the right. And when you try to slightly raise the small coil above the form, this picture only gets worse. Those. the scales should not go to the left through zero. If, when lifting, the scale readings still go through zero, it means that due to errors in the diameters of the wire or mandrels, it turned out to be small undercompensation. However, in this case, the sensor can also be balanced, which will be discussed below.

Consider a way to eliminate a small overcompensation. To do this, we need to slightly remove the compensating coil from the receiver. We do this with a wooden toothpick - we introduce it under the turns of the compensating coil and bend them slightly towards the center. At the same time, we monitor the readings, trying to get a zero balance on both scales. X and Y .

Because the wire of the compensating coil is quite rigid, the bent turns do not need additional fixation. Following the readings of the scales, we bend the required number of turns. If for the balance there are not enough turns of one sector between the thread ties, we move on to another sector. Having achieved readings close to zero at amplification 1, install Gain 8 and correct the position of the turns. Having achieved an unbalance of no worse than ±20%, preliminary balancing can be considered completed. We unsolder the cable and proceed to pouring the coils with epoxy resin. For these purposes, we need about 100-110 grams of resin. At the end of the filling, we bend the “tails” of the reinforcing tapes inside the “knitting needles” and leave the mold on a flat surface for 24 hours to solidify the resin.

After the resin hardens, remove the casting from the mold. At the same time, you can not spare the form - in the right places we chop it with scissors. We remove the plasticine, and through the resulting hole we stretch the ends of the wires to the other side of the casting. As a result, we get such an elegant and durable design:

Now the sensor needs to be shielded. For these purposes, we use the same conductive varnish based on nitro-lacquer and crushed graphite. Preparation details are described. In this design, it is not the housing that is shielded, but the directly filled coils. Using a brush, varnish the “small ring”. Do not forget to install a ground terminal - a small piece of stranded insulated wire, one end of which must be stripped and “fluffed”, and then lubricated with conductive varnish. For convenience, this conductor can be pre-fixed with a drop of hot melt adhesive.

Attention: The transmitting coil does not need to be shielded! In this design, it is not only redundant, but also harmful. It is redundant because the Koshchei-18M output stage has a very low impedance, so the transmitting coil is practically not subject to the capacitive effect. And it is harmful, because when the screen is close to the transmitting coil, tangible induction currents begin to flow in it, which lead to screen degradation and, as a result, to false responses.

Next, proceed to the placement of the sensor inside the case. We fasten the pressure seal to the bracket. It is advisable to fix the gland nut with some kind of glue or compound. Then we pass the end of the cable through the cable gland.

Now we bend this end of the cable and tightly lay it inside the bracket, then securely fix it with hot glue.

Next, we proceed to the preparation of the housing covers. On the top cover, using side cutters or a scalpel, you need to remove four bosses (blue arrows). Then we drill six holes with a diameter of 3mm and countersink them with a 6-7mm drill under the head of the self-tapping screw (green arrows). Then we drill a hole with a diameter of 7-8mm for the cable (red arrow). On the bottom cover, only remove the bosses. We do not throw away the bosses, they will be useful to us later.

Next, we thread the end of the cable into the hole on the cover and fasten the bracket using stainless steel screws 3x16mm. In the area of ​​\u200b\u200bthe “ears” of the bracket, to increase the strength of the connection, self-tapping screws 3x20mm or 3x25mm can be used. Attention: self-tapping screws must be stainless steel. They, unlike conventional steel ones, do not lead to unbalance of the sensor.

Now we need to fix the sensor inside the top case cover. To do this, lift the sensor and apply hot glue inside the case in the places shown by the arrows. The hot melt must be well heated. Then firmly press the sensor to the cover. At the cable exit point (blue arrow), the adhesive should protrude inward and seal hole around the cable. We orient the ends of the cable along the bottom of the formed “bath”, into which the final filling will be made, fixing the winding leads. Regarding hot glue, we want to note that “not all washing powders are equally good”J. Hot glue works very well TOPEX . Unlike cheap brands of glue, it gives a very reliable connection with polystyrene and epoxy casting.

Next, solder the ends of the coils to the cable according to the diagram that was given above. Please note that when using a cable BW 7809PL (or similar), the shielding of the coils goes only along the "ground" wire of the receiving coil. And the screen of the conductor connected to the transmitter is not connected to the ground in this connection. Therefore, care must be taken to ensure that these screens do not come into contact with each other during installation in the connector and the sensor!

We connect the sensor to the device, enter the service mode and check the balance. Now we will need to pay special attention to the leads from the thicker wire that are soldered to the cable. The position of these pins significantly affects the balance! Therefore, they need to be laid in an optimal way. These leads have the greatest sensitivity to balancing when laid next to the receiving coil. The direction of laying also matters. It depends on which direction we are moving - overcompensation or undercompensation. We follow the readings of the scales and stack the conclusions in such a way that the balance on both scales converges to zero (At Gain 8). On the X scale, an unbalance of ± 15% is acceptable. When laying, it is desirable to leave a small loop 1-2 cm in size, which will rise above the surface"baths".

Separately, we should dwell on the case when balancing with the help of the existing “tails” does not work. In this case, one of the conclusions should be extended with the same wire and laid along the perimeter inside the “bath”. Such a loop of wire plays the role of an auxiliary compensating winding. The laying direction is determined by the indications of the scales. In the case of a strong imbalance, several such turns may be required. In this way it is possible to "treat" and overcompensation, and undercompensation.

Next, we place the sensor strictly horizontally and fill the “bath” with epoxy resin. After the resin hardens, we check the balance again and, if necessary, correct it with the help of a loop remaining above the surface. The loop must be pressed to the surface and bent in an optimal way, following the readings of the scales.

Now you can glue the bottom cover to the sensor. In principle, any universal glue is suitable for this. But the best results are obtained by homemade glue, made by dissolving polystyrene in dichloroethane. For this, the previously removed bosses will fit us. We put them in some kind of vial, fill it with a small amount of dichloroethane and close it hermetically. Wait until the polystyrene is completely dissolved which usually takes a couple of hours. Then the mixture is stirred and, if necessary, diluted with dichloroethane to the density of sour cream. Attention: work with dichloroethane in a well-ventilated area, because its fumes are poisonous! Next, let's move on to gluing. To do this, gently glue the grooves on both halves with glue and squeeze them tightly. It is important not to overdo it with glue so that its remnants do not crawl out. By the way, one of the advantages of homemade glue is that it has the same color as the case. Therefore, small gluing flaws will be hardly noticeable. You should also pay attention that this glue dries quickly enough. Therefore, the lubrication process should not be strongly delayed (no longer than 5-10 minutes).

So, as a result of all the work, we got such a sensor.

We connect the sensor to Koshchei-18M and perform phase calibration of the path together with this sensor. We do this in the same way that was described in the previous chapters. In this instance, for a frequency of 7 kHz, the phase shift turned out to be 150.5 degrees, for 14 kHz - 173.6 degrees. We turn on the search modes, bring various typical targets to the sensor and make sure that the device detects and correctly recognizes them.

findings

In laboratory tests, the following parameters were obtained:

Sensor weight - 496g.

Air detection range (in selective mode):

5kop. USSR–30cm.

copper penny Alexei Mikhailovich–13cm.

Consumption at a frequency of 7 kHz - 143mA.

Consumption at a frequency of 14kHz - 83mA.

The electrical balance is maintained in the temperature range of -10…+50 degrees Celsius.

From the above figures it can be seen that the maximum depth of the sensor is not inferior to the parameters of the previous concentric sensor with a diameter of 200mm. At the same time, the new sensor has a much more elegant design, has a significantly lower weight. .With the described sensor, the power consumption of the device is noticeably lower. Also It should be noted that with the new ratio of the diameters of the receiving and transmitting coils (1:2 instead of 1:1.4), the sensitivity to small objects (for example, flake coins) has increased. But at the same time, the “taper” of the radiation pattern was somewhat sharpened.

In field tests, another useful feature was noticed - such a sensor is less prone to false responses when hitting branches, thick grass stalks, etc. Obviously, this is due to the fact that the sensor has a “soft suspension” inside the case.

Before I describe the technique itself, I want to draw attention to two points:

1. The device may start to fail if moisture gets into this socket (a cop in the rain, in a fog, accidentally lowered the metal detector into a puddle, and so on).
2. On different metal detectors, this socket can be located in different areas, so I will describe the very essence of the technique, and how to adapt some points to your metal detector - you will already figure it out on the spot.

I started protecting this nest exactly from the moment it was early spring, when the snow had almost melted, but in some areas it still lay in a decent layer, carefully put my metal detector next to the dug hole, and take the device and drop it, and block right into the puddle. I didn’t wet it very much, since there was a little case on the “brains”, but after this incident, phantom signals began to appear quite often. I did not immediately determine the reason, so I had to tinker. And the reason is that moisture got just on the thread of the socket, and then on the contacts.

And I also had a case when during the search it started to rain, and naturally, being on the field, everything got wet. I always carry a bag in my pocket that the ball is put on the block, but in this case, something went wrong. After the rain, about an hour and a half later, constant signals to everything began, even with the metal detector raised. The batteries are charged normally, the coil is intact, the block itself, it seems, did not get very wet, but moisture probably leaked into the nest. Maybe I didn't tighten the nut all the way, I don't know. But in order not to think about this topic anymore, I decided to come up with a way to increase the protection of this particular element of my detector.

An easy way to protect the nest on a metal detector

An ordinary bicycle camera, instant glue, electrical tape came to my aid. First, I cut out a rectangle from the camera and glued it to the side of my metal detector. I glued it in such a way that the piece of rubber from the bottom completely covered the entire lower part and slightly extended beyond the block. Then, from the same chamber, I cut out a cylinder, 7 centimeters long. I put this cylinder on the cable from the coil (on the section that enters the plug) so that a piece of the camera extends two or three centimeters beyond the cable. The rubber cylinder itself was tied to the cable with electrical tape. That's all.

It turns out that if it snows or rains, if the metal detector accidentally falls into the water, the chance that the cable connection area with the block will be wet is sharply reduced. From below there is a rubber protection, and a piece of the camera that protrudes beyond the cable, when the coil is connected to the device, fits snugly against the block body. Naturally, this method does not cancel the use of a cover for the block, and, of course, I still carry a plastic bag in my pocket. But with such a modification, I walk much more calmly, although I myself looks somewhat strange from the outside. But it is better to let it be strange than to completely fail at the current exchange rate.

Here is such a simple way, a minimum of time, available to absolutely everyone.

Your Alexander Maksimchuk!
The best reward for me as an author is your like on social networks (tell your friends about this article), also subscribe to my new articles (just enter your email address in the form below and you will be the first to read them)! Do not forget to comment on the materials, and also ask any questions you have about treasure hunting! I am always open to communication and try to answer all your questions, requests and comments! Feedback on our website works stably - do not be shy!

There are many reasons to overshadow your search, and I have already talked about this with you more than once. So, if we talk about fairly harmless moments, these are batteries forgotten at home, improper equipment, hope, perhaps in terms of orientation and finding a worthy place to search. There are many reasons, but there are also those that will result not only in the end of the search, but also in the acquisition of new parts and spare parts for your metal detector.

In fact, there are only a few such reasons: a broken coil, a broken metal detector unit, a broken rod. How can you break the "brains" of the device? Elementary: just drown the device or step on it. Everything is simple and clear. It is not for nothing that experienced search engines, going out in search of artifacts, in addition to the cover on the block, also wrap it with cellophane.

This is not some whim, this is just taking care of your metal detector. True, there is a nuance here, but I will talk about this some other time. Crushing a metal detector sensor or breaking a rod is a common occurrence. Anything can happen in the excitement of the search, therefore, by accidentally turning the wrong way, the treasure hunter suddenly realizes that he “hit” a certain amount, and the search for today can be considered completed.

Spontaneous Signals

But there is another factor that can both overshadow the search and completely discourage the desire to engage in this hobby in general - this is an incorrectly wound coil cable. Here's the thing. On the one hand, and I have already talked about this, with an incorrectly wound cable, there is every chance that with an unsuccessful swing, when the coil cable catches a little on the grass, the wire will simply fly out of the socket.

Another option is also possible, when the searcher determines the find in the dump, puts his next to him, and for convenience bends the coil. At the same time, if the cable is wound incorrectly, separation is inevitable. On the other hand, I had cases when I already thought that my metal detector had gone crazy, as spontaneous signals were tormented. As it turned out later, the whole thing was in the wrong winding of the cable.

Cable fixation

A lot has been written about how to wind the cable correctly, and some manufacturers even make videos on this topic so that users can see firsthand how and what to do. But, for some reason, attention is often paid only to the lower section of the cable, which is located directly at the coil itself; To be honest, I didn't really think about this before.

But, as it turned out in my case, additional fixation of the cable in two more places avoids some spontaneous signals. Perhaps the whole point is that in the area where the cable enters the metal detector unit, with weak fixation, some minimal movements may occur, which leads to a false signal. In general, I do this:

1. I fix the cable at the coil as recommended by the search community (to keep the coil free to move, and the cable does not stretch).
2. I make the second turn of electrical tape approximately in the middle of the assembled rod, additionally fixing the cable.
3. The third fixation area is located approximately 10-15 cm from the metal detector unit.

The time it takes to carry out these manipulations is minimal, and the result pleases me. At the same time, do not forget that the plug from the coil that you insert into the metal detector unit must be dry, since moisture on the contacts will not have the best effect on the operation of the detector. Well, the fixing nut itself needs to be tightened so that the cable does not hang out, otherwise, false signals cannot be avoided.

Here is such a simple observation, thanks to which my search, in my opinion, has become more productive.

P.S. Some time to fix the cable to the rod I used special Velcro, which, by the way, I already wrote about. But in the end, I returned to electrical tape again, since this material is more convenient for me, and in which case, electrical tape can be bought literally at any stall, be it a city or a village.

Your Alexander Maksimchuk!
The best reward for me as an author is your like on social networks (tell your friends about this article), also subscribe to my new articles (just enter your email address in the form below and you will be the first to read them)! Do not forget to comment on the materials, and also ask any questions you have about treasure hunting! I am always open to communication and try to answer all your questions, requests and comments! Feedback on our website works stably - do not be shy!