JP4768093B2 - Multi-rotation potentiometer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a multi-rotation potentiometer.
[0002]
[Prior art]
A general structure of a multi-rotation potentiometer is shown in FIG. As shown in FIG. 7A, this multi-rotation type potentiometer has a ring shape having a resistor 102 spirally arranged in a case 101 and a sliding contact portion 103a that is in sliding contact with the resistor 102. The rotating body 103 is provided. The rotating body 103 is inserted through the rotor shaft 109a, and rotates while sliding in the horizontal direction in the figure by rotating the shaft 109b, and the sliding contact portion 103a slides along the resistor 102. Let Both ends of the resistor 102 are connected to the first terminal 105 and the third terminal 107, respectively, and the sliding contact portion 103a is connected to the second terminal 106 via the collector 103b and the sliding piece 103c. By changing the contact position of the sliding contact portion 103a with the resistor 102, the resistance value between the second terminal 106 and the first terminal 105 (or the third terminal 107) can be made variable. Here, as shown in FIG. 7 (b), the resistor 102 is formed by spirally forming a resistance wire 102b such as Ni—Cr or Cu—Ni on an insulation wire 102a obtained by subjecting the surface of a copper (Cu) wire to insulation treatment. It is wrapped around.
[0003]
[Problems to be solved by the invention]
In such a multi-rotation potentiometer, since the resistance value changes depending on the contact position between the resistance wire 102b wound around the resistor 102 and the sliding contact portion 103a, the resistance value changes stepwise in terms of structure. The resistance value corresponding to one step of the resistance value changing stepwise is the resolution of the potentiometer, but there has been a demand for further reducing the resolution in order to detect minute fluctuations. Further, such a multi-rotation potentiometer is very troublesome in manufacturing the resistor 102 described above, and has been an obstacle to improving the productivity of the entire potentiometer. Further, since the resistance wire 102b and the sliding contact portion 103a having the same level of hardness are slid, the resistance wire 102b is likely to be worn, and a short circuit occurs between the adjacent resistance wires 102b. Further improvement was desired. In addition, there are many contacts sliding between the structures (between the resistor 102 and the sliding contact portion 103a, between the sliding contact portion 103a and the collector 103b, and between the sliding piece 103c and the second terminal 106), The contact resistance generated in this portion increases as the sliding is repeated, and this is a factor that lowers the reliability over time as a potentiometer.
[0004]
The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a multi-rotation potentiometer capable of improving resolution and improving productivity, durability, and reliability. To do.
[0005]
[Means for Solving the Problems]
The invention according to claim 1 includes a case, a resistor arranged in a spiral shape in the case, and a rotating body having a sliding contact portion and a disc portion that are in sliding contact with the surface of the resistor. In a rotary potentiometer,
A spiral resistor holding groove is formed along the inner surface of the case. The resistor holding groove has a bottom width substantially the same as the width of the resistor and the width of the opening of the resistor holding groove. The resistor has a concave shape wider than the width of the bottom, and the resistor is formed by laminating a conductive plastic layer on the surface of a tape-like insulating base material made of a heat-resistant film that can withstand heating and baking. The resistor is in close contact with the bottom of the resistor holding groove by its own elastic restoring force, the first terminal connected to one end of the resistor and exposed to the outside of the case, and the case connected to the sliding contact portion A second terminal exposed to the outside of the resistor and a third terminal connected to the other end of the resistor and exposed to the outside of the case, and one end of the conductive coil spring has an arm having a sliding contact portion The part is fixed to the joined disk part and is conductive The other end of Irubane is characterized in that it is fixed to the second terminal.
[0006]
The resistor according to the first aspect of the present invention has a tape-like shape in which a conductive plastic layer (hereinafter also referred to as “CP layer”) is laminated on an insulating base material. The moving contact part slides continuously. Therefore, according to the present invention, the extracted resistance value does not change stepwise, theoretically the resolution becomes infinitely small, and minute fluctuations can be detected. Moreover, in the production of this tape-shaped resistor, it is only necessary to laminate a CP layer on a film-like insulating base material and cut it into a tape shape, which is easy to produce and contributes to the productivity improvement of the potentiometer. can do.
[0007]
Further, the CP layer surface is excellent in slidability, and the wear of the sliding contact portion and the resistor can be suppressed to improve the durability, and the reliability over time can be improved. Further, since the resistor 2 is in the form of a tape, the contact state between the surface of the resistor and the sliding contact portion is stable, and the reliability can be improved from this point.
[0008]
Further , the resistor is in close contact with the inner surface of the case by its elastic restoring force . According to this configuration , the resistor is brought into close contact with the inner surface of the case by the elastic restoring force of the resistor itself, and the resistor is held in a stable state. In addition, while the sliding contact portion slides on the surface of the resistor, the resistor is in close contact with the inner surface of the case, so that the sliding contact portion can slide smoothly on the resistor surface. it can.
[0009]
Furthermore, a spiral resistor holding groove is formed along the inner surface of the case. The resistor holding groove has a bottom width substantially the same as the width of the resistor and an opening width of the bottom portion. It is a concave shape that is wider than the width. According to this configuration, when the resistor is stored in the resistor holding groove, the resistor can be easily stored by being guided on the slope of the resistor holding groove, leading to an improvement in productivity. In addition, since the width of the bottom of the resistor holding groove is substantially equal to the width of the resistor, the resistor can be reliably held.
Further, by forming the spiral resistor holding groove, it becomes easy to slide the sliding contact portion spirally using the resistor holding groove as a guide, and the resistor and the sliding contact portion can be stably slid. Can be moved.
[0010]
Further , a first terminal connected to one end of the resistor and exposed to the outside of the case, a second terminal connected to the sliding contact portion and exposed to the outside of the case, and connected to the other end of the resistor. and a third terminal which is exposed to the outside of the case Te, that have between the sliding contact portion and the second terminal is connected by the conductive co Irubane. According to this configuration , the sliding contact can be made only at one place between the resistor and the sliding contact portion, and the deterioration of reliability due to the increase of the sliding resistance with time can be prevented, and the durability reliability can be prevented. Can be improved.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of a multi-rotation potentiometer according to the present invention will be described with reference to the drawings.
[0012]
In the multi-rotation potentiometer shown in FIG. 1, a tape-shaped resistor 2 is spirally arranged in a case 1, and a rotating body 3 having a sliding contact portion 3 a that makes sliding contact with the resistor 2 is provided. It is attached to the rotor shaft 9a so as to slide in the horizontal direction in the figure while rotating. The case 1 includes an inner cylinder 10 made of synthetic resin and an outer cylinder 11 made of metal. The inner diameter of the outer cylinder 11 is substantially equal to the outer diameter of the inner cylinder 10, and a circular plate 4 having a diameter equal to the outer diameter of the inner cylinder 10 and the mount 9 c are brought into contact with both ends of the inner cylinder 10. The inner cylinder 11, the plate 4 and the mount 9 c are integrally held by the outer cylinder 11.
[0013]
As shown in FIG. 2, the resistor 2 has a CP layer 2b formed on an insulating base material 2a, and contact layers 2c are further laminated on the CP layer 2b at both ends thereof. The CP layer 2b is obtained by applying a thermosetting resin mixed with carbon in order to give conductivity to the insulating base material 2a and curing it by heating and baking. As the insulating base material 2a, a film having heat resistance that can withstand heat baking and moderately flexible deformation is used.
[0014]
The contact layer 2 c is a silver (Ag) pattern that serves as an electrode for applying a voltage across the resistor 2. In forming the contact layer 2c, it is cured by heating and baking using a silver paste. The contact layer 2c is formed by regulating the length L of the CP layer 2b, obtaining a detectable angle (effective electrical angle), and easily and reliably connecting to terminal springs 5b and 7b described later. Because. The CP layer 2b and the contact layer 2c are preferably applied by a screen printing method or a coating method using a drawing method in order to achieve a uniform layer thickness. This is because the resistance value per unit length is different if the layer thickness of the CP layer 2b is not uniform.
[0015]
When the resistor 2 is manufactured, the CP layer 2b is formed on the sheet-like insulating base material 2a, the contact layers 2c are formed on the opposite end edges, and the contact layer 2c is cut into a tape shape. Can be easily manufactured at once. On the other hand, in the case of the resistor 102 conventionally used as shown in FIG. 7 (b), the number of parts required to form the resistor 102 is large, and not only the process becomes complicated, but also one by one. Since it had to be manufactured, it was very laborious and costly. This is particularly noticeable because the length of the resistor 102 is increased when the potentiometer is a multi-rotation type. On the other hand, the multi-rotation potentiometer shown in FIG. 1 can dramatically improve the productivity.
[0016]
As shown in FIG. 3, the inner cylinder 10 to which the resistor 2 is attached has a spiral resistor holding groove 10 a formed on the inner surface thereof . Na us, FIG. 3, a state of being held a resistor 2 to the resistor holding groove 10a of the inner cylindrical body 10 is shown. The resistor holding groove 10a has a bottom width substantially equal to the width of the resistor 2, and an opening width wider than the bottom width. For this reason, the cross-sectional shape of the resistor holding groove 10a becomes a concave shape gradually narrowing toward the bottom, and when the resistor 2 is stored in the resistor holding groove 10a, the resistor 2 is guided, and thus the storing operation is performed. easy.
[0017]
When the resistor 2 is stored in the resistor holding groove 10a, the resistor 2 is inserted into the inner cylinder 10 while being held in a spiral shape, and is aligned with the spiral of the resistor holding groove 10a. Thereafter, when the force holding the resistor 2 in a spiral shape is removed, the resistor 2 expands by its own elastic restoring force, and as described above, the resistor 2 adheres to the bottom while being guided by the slope of the resistor holding groove 10a. Spread until you do. Thus, since the resistor 2 is in a tape shape and adheres to the inner surface of the case 1 by its own elastic restoring force, the sliding contact portion 3a can smoothly slide on the surface of the tape-shaped resistor 2. it can. Moreover, the resistor 2 can hold | maintain a helical form with its own elastic restoring force.
[0018]
Further, since the CP layer 2b is formed on the entire surface of the resistor 2, when the contact position of the sliding contact portion 3a with respect to the CP layer 2b of the resistor 2 is changed to change the resistance value, The resolution is theoretically infinitely small. For this reason, minute fluctuations can be detected. Further, since the resistor 2 is in the form of a tape, it is excellent in slidability, hardly wears, and durability and reliability over time are improved. Further, since the resistor 2 is in the form of a tape, the contact state with the sliding contact portion 3a is stable, and the reliability is improved from this point. Further, since the width of the resistor 2 held in the resistor holding groove 10a is equal to the width of the bottom of the resistor holding groove 10a, in addition to the shape holding effect by its own elastic restoring force, the resistor 2 When stored in the holding groove 10a, the position is reliably held.
[0019]
The accommodation state of the resistor 2 in the resistor holding groove 10a is such that the surface side of the CP layer 2b is on the inside of the spiral, but it is necessary to pay attention to the spiral diameter at this time. If the spiral diameter is too small, the stress applied to the CP layer 2b increases and cracks are likely to occur in the CP layer 2b. On the other hand, when the spiral diameter is too large, the elastic restoring force of the resistor 2 does not act effectively, and it is difficult to make it firmly adhere to the bottom of the resistor holding groove 10a.
[0020]
As shown in FIG. 2, both ends of the resistor 2 are held and fixed to the inner cylinder 10 by terminal springs 5b and 7b in the contact layer 2c. One end of each of the lead wires 5a and 7a is connected to each of the terminal springs 5b and 7b, and the other end of each of the lead wires 5a and 7a is connected to the first terminal 5 and the third terminal 7, respectively. In this potentiometer, both the first terminal 5 and the third terminal 7 are configured to be exposed from the plate 4, and the lead wire 5 a passes to the plate 4 side through a groove formed on the outer surface of the inner cylinder 10. Wired and connected to the first terminal 5. The first terminal 5 and the third terminal 7 are inserted into insertion holes 4a and 4b (see FIG. 4B) formed in the plate 4, respectively.
[0021]
As shown in FIGS. 4 and 5, the plate 4 is a substantially disk-shaped member made of synthetic resin. On the inner surface side, a plurality of arcuate walls 4c for standing with the inner cylindrical body 10 are provided upright. In addition to the above-described insertion holes 4a and 4b, the plate 4 is formed with an insertion hole 4d, and a second terminal 6 bent in an L shape is inserted into the insertion hole 4d. The insertion portion of the second terminal 6 into the plate 4 protrudes to the front surface side of the plate 4, and the back surface side of the plate 4 of the second terminal 6 is in contact with the plate 4. The insertion holes 4 a, 4 b, 4 d are arranged evenly with respect to the center of the plate 4.
[0022]
As shown in FIGS. 4 and 5, the rotating body 3 having the sliding contact portion 3 a that is in sliding contact with the resistor 2 includes an arm portion 3 b in which the sliding contact portion 3 a is formed at the tip, and this arm. The part 3b includes a disc part 3c to which the disc part 3c is attached and a holder part 3d to which the disc part 3c is attached. The sliding contact 3a is formed in a brush shape with the tip of the arm portion 3b branched into three. The arm part 3b is formed of a metal plate having an elastic restoring force. Moreover, the disc part 3c is formed with the metal which has electroconductivity, and has a square hole in the center. The disc portion 3c is joined to a tongue piece formed at a part of the peripheral edge thereof in a state where the base end of the arm portion 3b described above ensures conductivity by welding.
[0023]
Two circular holes are perforated adjacent to the central square hole in the disc part 3c, and the convex parts 3g, 3g of the holder part 3d are fitted into these hole parts, and the convex part 3g , 3g are caulked by heat, and the disc portion 3c and the holder portion 3d are coupled. A square hole is also formed on the holder portion 3d side, and an insertion hole 3f is formed together with the square hole on the disc portion 3c side. The holder portion 3d has a hollow inside, and a coil spring 8 described later is accommodated in the hollow portion. On the outer periphery of the holder portion 3d, a pair of guide convex portions 3e, 3e are formed so as to protrude laterally at positions separated by 180 °.
[0024]
The pair of guide convex portions 3e, 3e are formed as convex portions corresponding to the concave grooves of the resistor holding groove 10a described above. For this reason, when the rotating body 3 is attached to the inner cylindrical body 10, the guide convex portions 3e and 3e slide in the resistor holding grooves 10a, respectively, and guide the rotation and sliding of the rotating body 3. The rotor shaft 9a is inserted through the insertion hole 3f at the center of the rotating body 3. Further, one end 8b of the coil spring 8 penetrating the holder portion 3d is soldered to the disc portion 3c of the rotating body 3.
[0025]
The coil spring 8, as shown in FIG. 6 is a co Irubane like central coil portion 8a in the natural length state becomes dense. One end 8 b of the coil spring 8 extends linearly so as to be parallel to the central axis of the coil spring 8, and the other end 8 c extends radially outward from the central axis of the coil spring 8. However, in the state where the coil spring 8 is incorporated in the potentiometer, even when the rotating body 3 is located closest to the plate 4, the coil portion 8 a is stretched to some extent and a gap is always formed between the windings. It is assumed that When the rotating body 3 is rotated, the coil spring 8 is further extended while rotating the one end 8b in the R direction in FIG. 6A, that is, the direction in which the rotation of the coil spring 8 is twisted.
[0026]
One end 8 b of the coil spring 8 is soldered to the disc portion 3 c as described above, while the other end 8 c is soldered to the second terminal 6 attached to the plate 4. For this reason, the sliding contact portion 3a and the second terminal 6 are directly connected via the arm portion 3b, the disc portion 3c, and the coil spring 8. As a result, in this potentiometer, the sliding contact is only between the resistor 2 and the sliding contact portion 3a, so that an increase in contact resistance can be prevented, and reliability over time can be improved.
[0027]
When designing the coil spring 8, it is necessary to pay attention to the characteristics and shape of the spring. In consideration of the number of rotations of one end 8b of the coil spring 8 and the amount of displacement in the X direction in FIG. 1 while the sliding contact portion 3a spirally slides from one end side to the other end side of the resistor 2, Even when the displacement becomes the largest, the deformation of the coil spring 8 is set within the elastic range. In addition, rotating the coil spring 8 in the R direction in FIG. 6A, that is, in the direction of twisting with respect to the spiral of the coil spring 8, rotates the residual stress acting on the coil spring 8 in the direction opposite to the R direction. It is because it can be suppressed smaller than when it is made to. At this time, a rotor shaft 9a, which will be described later, serves as guide means for preventing buckling by restricting excessive movement of the coil spring 8 when the coil spring 8 is rotated in the R direction.
[0028]
As shown in FIG. 1, the rotor shaft 9a inserted through the insertion hole 3f of the rotating body 3 is connected to the shaft 9b. By rotating the shaft 9b from the outside of the case 1, the rotor shaft 9a is coupled with the shaft 9b. Rotate. The rotor shaft 9a has the same square cross-sectional shape as the insertion hole 3f at the center of the rotating body 3, and rotates the rotating body 3 as the rotor shaft 9a rotates. The rotor shaft 9a guides the sliding of the rotating body 3 when the rotating body 3 slides in the lateral direction in FIG.
[0029]
The shaft 9b is held by a mount 9c, and one end of the shaft 9b extends to the outside of the case 1. The mount 9c has a cylindrical portion 9d at the center thereof, and ensures sliding performance as a bearing for the shaft 9b. A metal bearing 9e is press-fitted or bonded inside the cylindrical portion 9d to suppress the backlash of the shaft 9b. Further, if necessary, a screw portion 9f used for fixing the potentiometer to various parts is formed on the outer surface of the cylindrical portion 9d.
[0030]
When the potentiometer composed of the above-described components is assembled, the rotating body 3, the plate 4, and the coil spring 8 are assembled in advance to produce a coil assembly. Next, mount 9c-inner cylinder 10-rotor shaft 9a and shaft 9b-coil assembly are sequentially attached to the outer cylinder 11, and finally the claws 11a of the outer cylinder 11 are bent to the surface side of the plate 4 for assembly. Complete.
[0031]
When using the potentiometer described above, a voltage is applied between the first terminal 5 and the third terminal 7, and the voltage is divided between the first terminal 5 (or the third terminal 7) and the second terminal. Take out the voltage. At this time, the resistance value between the first terminal 5 (or the third terminal 7) and the second terminal is changed by changing the contact position of the sliding contact portion 3a with respect to the resistor 2 by rotating the shaft 9b. The partial pressure taken out can be changed.
[0032]
The multi-rotation potentiometer of the present invention is not limited to the above-described embodiment. For example, the potentiometer in the above-described embodiment is such that the CP layer 2b of the resistor 2 is inside the spiral of the resistor 2, but the resistor is arranged so that the CP layer is outside the spiral, It is also possible to slide the sliding contact portion along the outer surface of the resistor.
[0033]
【The invention's effect】
A multi-rotation potentiometer according to the present invention includes a case, a resistor arranged in a spiral shape in the case, and a rotating body having a sliding contact portion and a disc portion that are in sliding contact with the surface of the resistor. In a multi-rotation potentiometer, a spiral resistor holding groove is formed along the inner surface of the case, and the resistor holding groove has a bottom width substantially the same as the width of the resistor and the resistor holding The width of the opening of the groove is a concave shape wider than the width of the bottom, and the resistor has a conductive plastic layer laminated on the surface of a tape-like insulating base material made of a heat-resistant film that can withstand heat firing. A first terminal exposed to the outside of the case connected to one end of the resistor, and a sliding contact, wherein the resistor is in close contact with the bottom of the resistor holding groove by the elastic restoring force of the resistor itself Connected to the A second terminal exposed to the outside of the resistor and a third terminal connected to the other end of the resistor and exposed to the outside of the case, and one end of the conductive coil spring has an arm having a sliding contact portion Since the other end of the conductive coil spring is fixed to the second terminal, the resolution can be improved and the productivity, durability, and reliability can be improved. .
[Brief description of the drawings]
1A is a cross-sectional view showing an embodiment of a multi-rotation potentiometer according to the present invention, and FIG. 1B is a side view taken in the direction of the arrow X in FIG.
2A is a plan view of a state in which a resistor is developed, and FIG. 2B is a cross-sectional perspective view taken along line II-II in FIG. 2A.
3A is a cross-sectional view of the inner cylinder in FIG. 1, FIG. 3B is a side view in the Y direction in FIG. 3A, and FIG. 3C is an X in FIG. It is a directional arrow side view.
4A is a front view of the coil assembly in FIG. 1, and FIG. 4B is a side view in the Y direction in FIG. 4A.
FIG. 5 is a front view showing each member in FIG. 4 (a) separately.
6 shows a natural state of the coil spring in FIGS. 4 and 5, wherein (a) is a left side view, (b) is a front view, and (c) is a right side view. FIG.
7A and 7B show a conventional multi-rotation potentiometer, in which FIG. 7A is a cross-sectional view, and FIG. 7B is a partial cross-sectional enlarged side view of a resistor.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Case, 10 ... Inner cylinder, 10a ... Resistor holding groove, 11 ... Outer cylinder, 2 ... Resistor, 2a ... Insulating base material, 2b ... Conductive plastic layer (CP layer), 3 ... Rotating body, 3a ... sliding contact part, 5 ... first terminal, 6 ... second terminal, 7 ... third terminal, 8 ... coil spring.

Claims (3)

In a multi-rotation potentiometer comprising a case, a resistor arranged spirally in the case, and a rotating body having a sliding contact portion and a disc portion that are in sliding contact with the surface of the resistor,
A spiral resistor holding groove is formed along the inner surface of the case, and the resistor holding groove has a bottom width substantially the same as the width of the resistor, and the resistor holding groove. The width of the opening is a concave shape wider than the width of the bottom,
The resistor is formed by laminating a conductive plastic layer on the surface of a tape-like insulating base material made of a heat-resistant film that can withstand baking by heating.
The resistor is in close contact with the bottom of the resistor holding groove by the elastic restoring force of the resistor itself,
A first terminal connected to one end of the resistor and exposed to the outside of the case; a second terminal connected to the sliding contact portion and exposed to the outside of the case; and the other end of the resistor And a third terminal exposed to the outside of the case.
One end of the conductive coil spring, said arm portions having a sliding contact portion is fixed to the disc portion coupled, the other end of the conductive coil spring is characterized in that fixed to said second terminal Multi Rotary potentiometer. The multi-rotation potentiometer according to claim 1, wherein the conductive coil spring is dense in a natural length state.   The depth of the resistor holding groove is such that when the resistor is housed in the resistor holding groove, the resistance in a direction perpendicular to the surface where the resistor and the bottom of the resistor holding groove are in contact with each other. The multi-rotation potentiometer according to claim 1 or 2, wherein the potentiometer is larger than the body.

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