JP2023048320A - Dial with potentiometer and rotary dial - Google Patents

Abstract

To provide a technique enabling a user to recognize that the electrical output of a potentiometer has reached a predetermined value or within a predetermined range without reading display contents of a scale portion.SOLUTION: A dial with a potentiometer includes a rotary dial and a potentiometer. The rotary dial has a knob that is rotated by a user, and a scale portion that changes display contents according to a rotation angle of the knob. The potentiometer outputs an electrical signal corresponding to the rotation angle of the knob. The rotary dial also has a notification unit that notifies the user of the fact that the electrical output of the potentiometer has satisfied a preset condition.SELECTED DRAWING: Figure 5

Description

The present invention relates to potentiometer dials and rotary dials.

2. Description of the Related Art Conventionally, rotary dials have been used in the industrial field, for example, for adjusting the volume of amplifiers and power supply equipment, or for incorporating them into control panels. Patent Literature 1 describes a technique related to an "LED indicator with a dial illumination function" including a knob having a skirt portion with a plurality of different numbers attached thereto, and an LED that illuminates a portion of the skirt portion.

Generally, rotary dials are used in combination with rotary potentiometers. Further, the rotary dial includes a knob that is rotated by the user and a scale portion that changes display contents according to the rotation angle of the knob. A potentiometer has a rotatable shaft attached to the rotary dial so that the shaft rotates together with the knob. A potentiometer attached to the rotary dial outputs an electrical signal corresponding to the rotation angle of the knob and shaft.

When the user rotates the knob of the rotary dial, both the display contents of the scale and the electrical output of the potentiometer change according to the rotation angle of the knob. For this reason, when checking and adjusting the shaft rotation angle and electrical output of the potentiometer, the user reads the content displayed on the scale (for example, a number of several digits) and confirms that the display content matches the target content. As you can see, it is necessary to rotate the knob.

Japanese Utility Model Laid-Open No. 2-24656

By the way, the content displayed on the scale of the rotary dial constantly changes while the user is turning the knob. For this reason, while the user is turning the knob, the display of the scale appears blurry to the user's eyes. In addition, the faster the user turns the knob, the more quickly the display on the scale changes, making it difficult for the user's eyes to read the content displayed on the scale. For this reason, in order for the user to recognize that the electrical output of the potentiometer has reached a predetermined value or within a predetermined range, it is necessary to stop the rotation of the knob from time to time and read the contents displayed on the scale each time. .

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to enable a user to know when the electrical output of a potentiometer has reached a predetermined value or within a predetermined range without reading the contents displayed on the scale. To provide a technology that can be recognized by

A dial with a potentiometer according to the present invention includes a rotary dial having a knob that is rotatably operated by a user, a scale part whose display contents change according to the rotation angle of the knob, and an electric signal that corresponds to the rotation angle of the knob. and a notification unit for notifying a user that the electrical output of the potentiometer has satisfied a preset condition.
Also, a rotary dial according to the present invention is used for the dial with a potentiometer.

According to the present invention, the user can be made to recognize that the electrical output of the potentiometer has reached a predetermined value or within a predetermined range without reading the contents displayed on the scale.

1 is a perspective view showing the configuration of a dial with a potentiometer according to an embodiment of the present invention; FIG. 1 is a plan view showing the configuration of a dial with a potentiometer according to an embodiment of the present invention; FIG. It is the figure which looked at the dial with a potentiometer shown in FIG. 2 from A1 direction. 1 is an exploded perspective view of a dial with a potentiometer according to an embodiment of the present invention; FIG. 1 is an exploded perspective view of a rotary dial according to an embodiment of the present invention; FIG. FIG. 6 is an exploded perspective view of the rotary dial according to the embodiment of the present invention, viewed from a direction different from that of FIG. 5; It is a figure for demonstrating the relationship between the rotating operation of a knob, and the display content of a scale part. FIG. 10 is a diagram (part 1) for explaining the procedure for assembling the rotary dial; FIG. 12 is a diagram (part 2) for explaining the procedure for assembling the rotary dial; FIG. 13 is a diagram (part 3) for explaining the procedure for assembling the rotary dial; FIG. 11 is a side view of the fully assembled rotary dial; FIG. 12 is a cross-sectional view taken along the line BB of FIG. 11; FIG. 12 is a bottom view of the rotary dial shown in FIG. 11; It is the figure which looked at the dial with a potentiometer shown in FIG. 2 from A2 direction. FIG. 15 is a cross-sectional view taken along line DD of FIG. 14; 15. It is the figure which expanded the E section of FIG. 4 is a block diagram schematically showing the control configuration of the dial with potentiometer according to the embodiment of the present invention; FIG. FIG. 4 is a diagram showing the relationship between the knob rotation angle of a rotary dial and the output voltage ratio of a multi-rotation potentiometer;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the present specification and drawings, elements having substantially the same function or configuration are denoted by the same reference numerals, and overlapping descriptions are omitted.

(Configuration of dial with potentiometer)
FIG. 1 is a perspective view showing the configuration of a dial with a potentiometer according to an embodiment of the invention. 2 is a plan view showing the configuration of the dial with a potentiometer according to the embodiment of the present invention, and FIG. 3 is a view of the dial with a potentiometer shown in FIG. 2 as seen from the A1 direction. In this embodiment, for convenience of explanation, the up-down direction and the left-right direction are defined based on the case where the dial with the potentiometer is arranged in the orientation shown in FIG. However, the direction in which the user actually uses the dial with the potentiometer is not limited to the direction shown in FIG. 3. For example, the direction shown in FIG. may be in the direction of

As shown in FIGS. 1 to 3, the potentiometer dial 10 integrally includes a rotary dial 11 and a multi-rotation potentiometer 12 . The rotary dial 11 has a knob 21 , a cover 22 , a scale portion 23 and a locking lever 24 . The scale portion 23 is provided separately from the knob 21 so that the positions of the scale portion 23 and the knob 21 do not overlap when the rotary dial 11 is viewed from above (front) as shown in FIG.

The multi-rotation potentiometer 12 is a rotary potentiometer with an electrical rotation angle greater than 360°. In this embodiment, as an example, it is assumed that the electrical rotation angle of the multi-rotation potentiometer 12 is 3600°. A multi-turn potentiometer 12 is attached to the rotary dial 11 via a mounting panel 13 .

FIG. 4 is an exploded perspective view of a dial with a potentiometer according to an embodiment of the present invention;
As shown in FIG. 4, the multi-rotation potentiometer 12 includes a housing case 31, a shaft 32, a spigot portion 33, a mounting screw portion 34, a detent pin 35, three terminals 36a, 36b, 36c, It has The terminals 36a and 36c are connected to terminals (hereinafter referred to as "power supply terminals") of a power supply device (not shown) by lead wires. A power supply must be prepared by the user separately from the rotary dial 11 and the multi-rotation potentiometer 12 . The terminal 36b is a terminal for outputting an electric signal of the multi-rotation potentiometer 12. FIG. The electrical output of the multi-rotation potentiometer 12 may be any output that changes according to the rotation angle of the shaft 32 . For example, the multi-rotation potentiometer 12 outputs an electrical signal indicating a voltage value corresponding to the rotation angle of the shaft 32 from the terminal 36b. Thus, the electrical output of multi-turn potentiometer 12 is represented by a voltage value. Assuming that the power supply voltage supplied from the power supply device to the multi-rotation potentiometer 12 is, for example, 5V, this voltage value varies in the range from 0V to 5V according to the rotation angle of the shaft 32 .

On the other hand, the mounting panel 13 has a potentiometer mounting hole 37 , a first anti-rotation hole 38 , a second anti-rotation hole 39 , and a lead wire drawing hole 40 . The mounting panel 13 is a metal panel, and is formed in a flat plate shape that is quadrangular in plan view (square in the figure). The planar view shape and outer dimensions of the mounting panel 13 can be changed as needed.

The mounting bracket 41 and the nut 42 are members for mounting the multi-rotation potentiometer 12 to the rotary dial 11 via the mounting panel 13 . The mounting bracket 41 is formed in an annular shape. The mounting bracket 41 is integrally formed with three dial fixing claws 43 and one detent claw 44 . The dial fixing claw 43 is bent upward, and the detent claw 44 is bent downward.

(Structure of rotary dial)
5 is an exploded perspective view of a rotary dial according to an embodiment of the present invention, and FIG. 6 is an exploded perspective view of the rotary dial according to an embodiment of the present invention viewed from a direction different from that of FIG. .
As shown in FIGS. 5 and 6, the rotary dial 11 includes, in addition to the knob 21, the cover 22, and the locking lever 24, a case 45, a rotating mechanism section 46, an illumination section 30, and a buzzer board. 48 and a transparent plate 49 . Further, the rotary dial 11 includes a rotary drum unit 51, a mask plate 52, a lens cover 53, and a pinion 54 (see FIG. 5). The rotating drum unit 51, the mask plate 52, and the lens cover 53 are members that constitute the scale portion 23 (see FIGS. 1 and 2).

The knob 21 is a member made of resin that is rotated by the user. The knob 21 is a hollow member that integrally includes a top plate portion 21a and side plate portions 21b. The top plate portion 21a is circular in plan view, and the side plate portion 21b is cylindrical. The side plate portion 21b is formed to widen at the bottom. A notch portion 21c (see FIG. 6) is formed in the lower end portion of the side plate portion 21b, and unevenness is formed on the outer surface of the side plate portion 21b so that the user can easily hold and operate the side plate portion 21b. The knob 21 opens downward.

The cover 22 is a metal member that covers the case 45 . The cover 22 is formed in a rectangular shape in plan view. The cover 22 has a square hole 56 , a round hole 57 , four lens cover mounting holes 58 , and an escape portion 59 . The upper surface of the cover 22 is stepped with a height difference. The square hole 56 is formed in the top surface portion of the cover 22 on the high side, and the round hole 57 is formed in the top surface portion of the cover 22 on the low side. The square hole 56 and the round hole 57 are arranged side by side in the longitudinal direction of the cover 22 . Four lens cover attachment holes 58 are arranged around the square hole 56 . The relief portion 59 is provided on the lateral side portion of the cover 22 on the short side. The relief portion 59 is cut in a concave shape to avoid interference with the locking lever 24 .

The lock lever 24 is a lever for locking the rotation of the knob 21 and releasing the lock. As shown in FIG. 6, the locking lever 24 is provided so as to be able to reciprocate in the C direction about the central axis of the rotating mechanism 46. As shown in FIG. When the lock lever 24 is moved in one direction in the C direction, the rotation of the knob 21 is locked, and when the lock lever 24 is moved in the other direction in the C direction, the rotation lock of the knob 21 is released. That is, it becomes an unlocked state.

The case 45 is made of metal. The case 45 rotatably supports the rotating mechanism 46, the rotating drum unit 51, and the pinion 54, respectively. The upper surface of the case 45 is provided with four mask plate mounting projections 55a and two spacer projections 55b. The spacer convex portion 55b is a convex portion for securing a gap between the cover 22 and the case 45 so that the cover 22 does not interfere with the G-shaped ring 66 when the cover 22 is attached to the case 45 . 13, a plurality of claw grooves 83 and one opening 84 are formed on the bottom side of the case 45. As shown in FIG. The claw groove 83 is a groove for fitting the dial fixing claw 43 of the mounting bracket 41 shown in FIG. The opening 84 allows the power supply lead wire and the electrical signal input lead wire connected to the buzzer substrate 48 to be led out through the lead wire lead-out hole 40 (see FIG. 4) provided in the mounting panel 13 . formed for

The rotating mechanism section 46 includes a rotating shaft 61 made of metal and a bearing member 62 made of metal (see FIG. 12). A circumferential groove 61 a is formed in the rotating shaft 61 . The rotating shaft 61 is rotatably attached to the case 45 with a G-shaped ring 66 . The bearing member 62 is formed in an annular shape. The bearing member 62 is attached to the inner peripheral side of the rotating shaft 61 so as to rotate together with the rotating shaft 61 . A set screw 67 is attached to the rotation mechanism section 46 . The set screw 67 is a set screw with a hexagonal hole. The press screw 67 is engaged with a screw hole provided in the bearing member 62 . A set screw 67 is pressed against the shaft 32 of the multi-turn potentiometer 12 inserted into the bearing member 62 . With the set screw 67 pressed against the shaft 32 in this way, when the user rotates the knob 21 , the rotating shaft 61 , the bearing member 62 and the shaft 32 rotate together with the knob 21 .

The illumination section 30 includes an illumination substrate 47, a light emitting element 68, and a fixed resistor 65 (see FIG. 16). The illumination board 47 is configured by a printed wiring board. Two light emitting elements 68 serving as illumination light sources and fixed resistors 65 for limiting the current flowing through each light emitting element 68 are mounted on the illumination substrate 47 . The light emitting element 68 is composed of a side emitting type full color LED (light emitting diode) or a multicolor LED. In this embodiment, as an example, it is assumed that the light emitting element 68 is composed of a full-color LED. Although not shown, the light emitting element 68 includes a red light emitting LED chip, a blue light emitting LED chip, and a green light emitting LED chip. It has a configuration in which the 68 emission colors can be changed. The emission color of the light emitting element 68 corresponds to the color of the illumination light emitted by the illumination light source. The light emitting surface of each light emitting element 68 is arranged facing the same direction. Further, two fixing holes 69 are provided in the illumination board 47 . The fixing holes 69 are holes for fixing the illumination substrate 47 to the mask plate 52 using screws 70 .

The buzzer board 48 is configured by a printed wiring board. A buzzer 71 and a semiconductor device 72 (see FIG. 5) are mounted on the buzzer substrate 48 . Buzzer 71 is a chip-like sound component, for example, a piezoelectric buzzer. The semiconductor device 72 is a surface-mounted semiconductor device that functions as a microcontroller. The buzzer substrate 48 is also provided with two fixing holes 73 . The fixing holes 73 are holes for fixing the buzzer board 48 to the case 45 using screws 74 .

The transparent plate 49 is a member attached to the lens cover 53 . The transparent plate 49 is made of a resin having such a transparency that the content displayed on the scale portion 23 can be read through the transparent plate 49 . Examples of the resin forming the transparent plate 49 include acrylic resin. The transparent plate 49 is formed in a substantially rectangular shape in plan view. The transparent plate 49 is integrally formed with a round convex portion 76 . The convex portion 76 is formed in a chevron shape when viewed from the longitudinal direction of the transparent plate 49 .

The rotary drum unit 51 is composed of three rotary drums rotatably supported by a common drum support shaft (not shown). The three rotating drums display numbers from the 1st to the 3rd digits. Numbers from 0 to 9 (not shown) are attached to the outer peripheral surface of each rotating drum. Also, although not shown, circumferential grooves are formed between the rotating drums, and intermittent gears are attached to portions of the circumferential grooves.

The mask plate 52 is a flat member made of metal. The mask plate 52 is provided with three reading holes 77 , four through holes 78 and two screw holes 79 . The reading holes 77 are holes for the user to read the three-digit numbers displayed by the three rotating drums described above. The through holes 78 are holes for attaching the mask plate 52 to the case 45 . The screw holes 79 are holes for attaching the illumination substrate 47 to the mask plate 52 using the two screws 70 described above.

The lens cover 53 is a plate-like member made of resin. The lens cover 53 is attached to the cover 22 so as to shield the illumination board 47 . A window portion 81 is formed in the lens cover 53 . The window 81 has a rectangular opening so that the three reading holes 77 described above are not blocked by the lens cover 53 . Further, the window portion 81 is formed so as to pass through the lens cover 53 . Four convex portions 82 (see FIG. 8) are provided on the lower surface of the lens cover 53 .

Two pinions 54 are mounted side by side on the drive shaft 85 as shown in FIG. The drive shaft 85 is fixed to the case 45 with an adhesive or the like, and the drum support shafts supporting the respective rotating drums are also fixed to the case 45 with an adhesive or the like. Further, the case 45 incorporates a gear transmission mechanism (not shown). The gear transmission mechanism is a mechanism that transmits the rotational force of the knob 21 to the rotating drum of the first digit when the user rotates the knob 21 . The rotational force of the rotating drum of the first digit is transmitted to the rotating drum of the second digit via one of the pinions 54 and the intermittent gear meshing with it. In addition, the rotational force of the rotating drum of the second digit is transmitted to the rotating drum of the third digit via the other pinion 54 and the intermittent gear meshing therewith. As a result, the three rotary drums from the first to third digits rotate independently, and the rotation of each rotary drum changes the three-digit number displayed on the scale 23 from [000] to [000]. It is configured to change up to [999]. As shown in FIG. 7, the rotary dial 11 displays a three-digit number on the scale 23 according to the rotation angle when the knob 21 is rotated clockwise (CW direction). there is Further, when the knob 21 is rotated once clockwise, the three-digit number displayed on the scale portion 23 is incremented by "100", and when the knob 21 is rotated once counterclockwise, the number is displayed on the scale portion 23. The system is designed so that the three-digit number that is displayed is moved down by "100".

(Assembly procedure for rotary dial)
Next, the procedure for assembling the rotary dial according to the embodiment of the invention will be described. The assembly procedure described below is merely an example, and the rotary dial 11 may be assembled in a different procedure.

First, the rotating mechanism 46 and the rotating drum unit 51 are attached to the case 45, and the drive shaft 85 is attached to the case 45 so that the pinion 54 meshes with the above-described intermittent gear.

Next, the mask plate 52 is attached to the case 45 . Specifically, after the four mask plate mounting projections 55a provided on the case 45 and the four through holes 78 provided on the mask plate 52 are fitted, each mask plate projecting from the mask plate 52 The mask plate 52 is fixed to the case 45 by crimping the mounting projections 55a.

Next, the illumination substrate 47 is attached to the mask plate 52 using two screws 70 . Next, the buzzer board 48 is attached to the case 45 using two screws 74 . Either the illumination substrate 47 or the buzzer substrate 48 may be attached first. Also, the mask plate 52 may be attached to the case 45 after the illumination substrate 47 is attached to the mask plate 52 . Although not shown, the lighting substrate 47 and the buzzer substrate 48 are electrically connected by lead wires, and the buzzer substrate 48 has lead wires for power supply and lead wires for inputting electric signals. electrically connected. A lead wire for supplying power and a lead wire for inputting an electric signal are drawn out from an opening 84 (see FIG. 13) provided on the bottom side of the case 45 . A lead wire for power supply is connected to a power terminal of a power supply device (not shown). Thereby, the buzzer 71 and the semiconductor device 72 on the buzzer board 48 can be driven by the power supplied from the power supply device. A lead wire for electrical signal input is connected to the terminal 36 b of the multi-rotation potentiometer 12 . Thereby, the electrical output of the multi-rotation potentiometer 12 can be taken into the semiconductor device 72 on the buzzer substrate 48 .

Next, as shown in FIG. 8, the lens cover 53 is attached to the cover 22 . Specifically, after the four projections 82 provided on the lower surface of the lens cover 53 and the four lens cover mounting holes 58 provided in the cover 22 are fitted, each of the projections projecting inside the cover 22 The lens cover 53 is fixed to the cover 22 by crimping the convex portion 82 . At this time, the window portion 81 of the lens cover 53 is aligned with the rectangular hole 56 (see FIG. 5) of the cover 22 .

Next, the transparent plate 49 is attached to the cover 22 . Specifically, the convex portion 76 of the transparent plate 49 is fitted into the square hole 56 from the inside of the cover 22, and in this state, the contact surfaces of the cover 22 and the transparent plate 49 are fixed with an adhesive. Thereby, the lens cover 53 and the transparent plate 49 are attached to the cover 22 as shown in FIGS. Also, the convex portion 76 of the transparent plate 49 is arranged to face the window portion 81 of the lens cover 53 .

After that, the cover 22 is attached to the case 45 . Specifically, the rotating shaft 61 of the rotating mechanism 46 attached to the case 45 is passed through the round hole 57 of the cover 22, and the case 45 and the cover 22 are fitted together. Affix the surface with adhesive.

Next, the knob 21 is attached to the rotating shaft 61 of the rotating mechanism section 46 . Specifically, after applying an appropriate amount of adhesive to the circumferential groove 61a of the rotating shaft 61, the knob 21 is put on the rotating shaft 61 by aligning the position of the set screw 67 (see FIG. 6) with the position of the notch 21c. Thus, the knob 21 is fixed to the rotary shaft 61 with the adhesive.

This completes the assembly of the rotary dial 11 . FIG. 11 is a side view of the fully assembled rotary dial. 12 is a cross-sectional view taken along line BB of FIG. 11, and FIG. 13 is a bottom view of the rotary dial shown in FIG.

Next, a procedure for attaching the multi-rotation potentiometer 12 to the rotary dial 11 will be described.
First, the mounting panel 13 is attached to the multi-turn potentiometer 12 . The mounting panel 13 is mounted according to the following procedure. First, the shaft 32 of the multi-rotation potentiometer 12 is inserted into the potentiometer mounting hole 37 of the mounting panel 13 . Next, the anti-rotation pin 35 is fitted into the first anti-rotation hole 38 and the spigot joint portion 33 is fitted into the potentiometer mounting hole 37 . As a result, the multi-rotation potentiometer 12 is prevented from rotating with respect to the mounting panel 13, and the central axis of the potentiometer mounting hole 37 and the central axis of the shaft 32 are aligned. Further, the shaft 32 is arranged to protrude from the mounting panel 13 .

Next, the mounting bracket 41 is passed through the shaft 32 . At this time, the anti-rotation pawl 44 is fitted into the second anti-rotation hole 39 . As a result, the mounting bracket 41 is prevented from rotating with respect to the mounting panel 13 . Next, the nut 42 is passed through the shaft 32 . Next, the nut 42 is engaged with the mounting screw portion 34 , and the nut 42 is tightened in this state to bring the lower surface of the mounting panel 13 into close contact with the end surface of the housing case 31 .
The attachment panel 13 can be attached to the multi-rotation potentiometer 12 by the above procedure.

After that, the shaft 32 of the multi-rotation potentiometer 12 is inserted into the bearing member 62 of the rotation mechanism part 46 while aligning the claw groove 83 of the case 45 with the dial fixing claw 43 of the mounting bracket 41 . Also, the three dial fixing claws 43 are fitted into the corresponding claw grooves 83 . Also, the mounting panel 13 is pressed against the case 45 so that the top surface of the mounting panel 13 is in close contact with the bottom surface of the case 45 . The shaft 32 is fixed to the bearing member 62 by rotating the set screw 67 using a tool such as a hexagon wrench while maintaining the pressed state. As a result, the knob 21 and the shaft 32 are connected via the rotating mechanism portion 46 . Therefore, the shaft 32 rotates integrally with the knob 21 . Therefore, in the dial 10 with potentiometer, the rotation angle of the knob 21 and the rotation angle of the shaft 32 are the same.

When the shaft 32 is inserted into the bearing member 62 as described above, the power supply lead wire and the electric signal input lead wire connected to the buzzer board 48 of the rotary dial 11 are attached respectively. Each lead wire is led out to the housing case 31 side of the multi-rotation potentiometer 12 by passing it through the lead wire lead-out hole 40 of the panel 13 . After fixing the shaft 32 to the bearing member 62 with the press screw 67 as described above, the lead wire for inputting electrical signals is connected to the terminal 36b of the multi-rotation potentiometer 12. FIG.

By attaching the multi-turn potentiometer 12 to the rotary dial 11 in this way, the potentiometer-equipped dial 10 shown in FIGS. 14 and 15 is obtained. 14 is a view of the dial with a potentiometer shown in FIG. 2 as seen from direction A2, and FIG. 15 is a cross-sectional view taken along line DD of FIG. Moreover, FIG. 16 is the figure which expanded the E section of FIG.
As shown in FIGS. 14 to 16, the upper peripheral surface of the drum outer peripheral surface of the rotary drum unit 51 is close to and faces the convex portion 76 of the transparent plate 49 through the reading hole 77 (see FIG. 16) of the mask plate 52. placed in a state where Therefore, the user can read the numbers attached to the drum outer peripheral surface of the rotary drum unit 51 through the convex surface portion 76 of the transparent plate 49 .

At that time, due to the lens effect of the convex portion 76, the numbers appear large to the user's eyes. In other words, the numbers attached to the outer peripheral surface of the drum are enlarged and displayed by the convex portion 76 . Therefore, the numbers displayed on the scale portion 23 are easier to read.

Two light emitting elements 68 are arranged near the transparent plate 49 . Each light emitting element 68 emits illumination light 63 toward the convex surface portion 76 of the transparent plate 49 which is one component of the scale portion 23 . As a result, the convex surface portion 76 and the upper peripheral surface of the drum outer peripheral surface facing the convex surface portion 76 are brightly illuminated. Therefore, the user can read the numbers displayed on the scale portion 23 even when using the potentiometer-equipped dial 10 in a dim environment.

The transparent plate 49 is placed over the mask plate 52 , and the illumination substrate 47 is placed over the mask plate 52 so as to be adjacent to the transparent plate 49 . The light-emitting element 68 emits the illumination light 63 in a direction perpendicular to the thickness direction of the illumination substrate 47 (horizontal direction in FIG. 16). As a result, the lighting substrate 47, the fixed resistor 65, and the light emitting element 68, which are electronic components that constitute the lighting section 30, can be incorporated in a space-saving manner. Further, by irradiating the convex portion 76 with the illumination light 63 emitted by the light emitting element 68 in a direction orthogonal to the thickness direction of the illumination substrate 47, the entire scale portion 23 including the transparent plate 49 can be illuminated more brightly. can.

Furthermore, by arranging the thick convex surface portion 76 in the portion irradiated with the illumination light 63 emitted from the light emitting element 68, the illumination light 63 is sufficiently received by the convex surface portion 76, and the color of the illumination light 63 is reflected on the convex surface. It can be reflected in the color of the portion 76 . Therefore, the user looking into the scale portion 23 can easily perceive the color of the illumination light 63 .

Power is supplied to the multi-rotation potentiometer 12 by connecting the terminals 36a and 36c of the multi-rotation potentiometer 12 and the power supply terminals of the power supply device with lead wires (not shown) as described above. Power is supplied to the electronic components of the rotary dial 11 by connecting the lighting substrate 47 and the buzzer substrate 48 with a lead wire (not shown), and connecting the buzzer substrate 48 and the power supply device with a lead wire (not shown). (not shown)). In that case, power is supplied to the light emitting element 68 on the lighting board 47 via the buzzer board 48 . Also, the current flowing through the red, blue, and green LED chips of the light emitting element 68 is controlled by the microcontroller of the semiconductor device 72 .

FIG. 17 is a block diagram schematically showing the control configuration of the dial with potentiometer according to the embodiment of the present invention.
In FIG. 17, the control section 50 is a functional section implemented by a microcontroller of a semiconductor device 72 mounted on the buzzer board 48 . The control unit 50 also functions as a notification unit that notifies the user that the electrical output of the multi-rotation potentiometer 12 has satisfied a preset condition. In order for the controller 50 to function as a notification unit, the multi-rotation potentiometer 12, the two light emitting elements 68, and the buzzer 71 are electrically connected to the controller 50, respectively. As a result, the electrical output of the multi-rotation potentiometer 12 is taken into the controller 50 . Further, the driving of each light emitting element 68 and the driving of the buzzer 71 are controlled by the controller 50 based on the electrical output of the multi-rotation potentiometer 12 .

A specific configuration example of the control unit 50 and a control method will be described below.
First, the control unit 50 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory), which are not shown, as computer hardware resources. The ROM stores a control program. The CPU controls the light emitting element 68 and the buzzer 71 by reading the program stored in the ROM into the RAM and executing it. In addition, the program stored in the ROM includes a program for determining the magnitude of the current flowing through the red, blue, and green LED chips of the light emitting element 68, in other words, for determining the color of light emitted by the light emitting element 68. Parameters (hereinafter referred to as “light emitting element parameters”) and parameters for switching the on/off state of the buzzer 71 (hereinafter referred to as “buzzer parameters”) are set. Both the light emitting element parameter and the buzzer parameter are parameters for controlling the light emitting element 68 and the buzzer 71 based on the electrical output of the multi-rotation potentiometer 12 .

In this embodiment, as an example, the controller 50 recognizes the electrical output of the multi-rotation potentiometer 12 as the output voltage ratio. It is also assumed that the electrical output of the multi-rotation potentiometer 12 changes linearly in proportion to the rotation angles of the knob 21 and shaft 32 . It is also assumed that the electrical output of the multi-rotation potentiometer 12 increases when the shaft 32 is rotated clockwise and decreases when the shaft 32 is rotated counterclockwise.

Therefore, when the electrical output of multi-rotation potentiometer 12 varies, for example, from 0 V to 5 V, control unit 50 sets the output voltage ratio to 0 if the electrical output of multi-rotation potentiometer 12 is 0 V. %, and if the electrical output of the multi-rotation potentiometer 12 is 2.5V, the output voltage ratio is recognized as 50%, and if the electrical output of the multi-rotation potentiometer 12 is 5V, the output voltage ratio is 100%. % will be recognized.

On the other hand, the light-emitting element parameter is set when the output voltage ratio based on the electric output of the multi-rotation potentiometer 12 (hereinafter also simply referred to as "output voltage ratio") is 0% and 100%. When the emission color is red, and when the output voltage ratio is more than 0% and 10% or less and when the output voltage ratio is more than 90% and less than 100%, the emission color of the light emitting element 68 is yellow, and when the output voltage ratio is more than 10% and 90% or less. is set so that the light emission color of the light emitting element 68 is white. In this case, four parameters (0%, 10%, 90%, 100%) may be set as parameters for the light emitting element.

The buzzer parameters are such that the buzzer 71 is turned on when the output voltage ratio of the multi-rotation potentiometer 12 is 0% and 100%, and the buzzer 71 is turned off when the output voltage ratio is more than 0% and less than 100%. It is set in the condition to become a state. The ON state of the buzzer 71 is the state in which the buzzer 71 sounds, and the OFF state of the buzzer 71 is the state in which the buzzer 71 does not sound. In this case, two parameters (0%, 100%) may be set as buzzer parameters.

On the other hand, the three-digit number displayed on the scale portion 23 changes from [000] to [999] according to the rotation angle of the knob 21 . That is, the display contents of the scale portion 23 change according to the rotation angle of the knob 21 .

Also, in the dial 10 with potentiometer, the three-digit number displayed on the scale 23 and the output voltage ratio of the multi-rotation potentiometer 12 are adjusted so as to satisfy the following relationship. Here, a case where the knob 21 of the rotary dial 11 is a 10-rotation type and the rotation angle of the multi-rotation potentiometer 12 is 3600° will be described as an example.

First, when the output voltage ratio is 0%, the number displayed on the scale portion 23 is [000].
Further, when the output voltage ratio is more than 0% and 10% or less, the number displayed on the scale portion 23 becomes [more than 000 and 100 or less].
Further, when the output voltage ratio is over 10% and 90% or less, the number displayed on the scale portion 23 becomes [over 100 and 900 or less].
Further, when the output voltage ratio is more than 90% and less than 100%, the number displayed on the scale portion 23 is [more than 900 and less than 999].
When the output voltage ratio is 100%, the number displayed on the scale 23 returns to [000]. In other words, when the knob 21 is rotated 10 clockwise from the state where [000] is displayed on the scale portion 23, the display content of the scale portion 23 returns to the original state, that is, [000].

FIG. 18 is a diagram showing the relationship between the knob rotation angle of the rotary dial and the output voltage ratio of the multi-rotation potentiometer.
As shown in FIG. 18, the output voltage ratio of the multi-rotation potentiometer 12 changes from 0% to Varies up to 100%. The electrical rotation angle of the multi-rotation potentiometer 12 is set to 3600°. Also, the mechanical rotation angle of the rotary dial 11 is set to 3600°+α. That is, the mechanical rotation angle is set slightly larger than the electrical rotation angle. A minute interval corresponding to half the difference between the mechanical rotation angle and the electrical rotation angle is set at the clockwise terminal Ecw and the counterclockwise terminal Eccw. The mechanical rotation angle is the angle by which the knob 21 of the rotary dial 11 is mechanically rotated. The electrical rotation angle is the range in which the voltage value of the electrical signal (electrical output) output from the multi-rotation potentiometer 12 changes.

Also, the output voltage ratio of the multi-rotation potentiometer 12 is the power supply voltage applied to the terminals 36a and 36c of the multi-rotation potentiometer 12, and the electrical signal (electrical voltage) output from the terminal 36b of the multi-rotation potentiometer 12 output), expressed as a percentage. Therefore, for example, if the power supply voltage supplied to terminals 36a and 36c of multi-rotation potentiometer 12 is 5V, and the voltage value of the electrical output taken out from terminal 36b of multi-rotation potentiometer 12 is 2.5V. , the output voltage ratio of the multi-turn potentiometer 12 becomes 50%. In other words, the electrical output of the multi-rotation potentiometer 12 and the output voltage ratio based thereon are substantially equivalent except that the units for handling numerical values are different.

The control unit 50 controls the light emitting element 68 and the buzzer 71 as follows in relation to the above-described relationship between the knob rotation angle and the output voltage ratio.
When power is supplied to the buzzer board 48 through lead wires from a power supply device (not shown) and the electrical output of the multi-rotation potentiometer 12 is received by the control unit 50 through lead wires, the electrical output is compared with the parameters for the light emitting element and the parameters for the buzzer. When the output voltage ratio of the multi-rotation potentiometer 12 is 0% and 100%, the control unit 50 lights the light-emitting element 68 in red. %, the light emitting element 68 is lit yellow, and when the output voltage ratio is more than 10% and 90% or less, the light emitting element 68 is lit white. That is, the controller 50 changes the color of the illumination light 63 when the electrical output of the multi-rotation potentiometer 12 satisfies a predetermined condition. As a specific example, the controller 50 changes the color of the illumination light 63 from red to yellow when the output voltage ratio of the multi-rotation potentiometer 12 changes from 0% to 1%. Further, the control unit 50 changes the color of the illumination light 63 from white to yellow when the output voltage ratio of the multi-rotation potentiometer 12 changes from 90% to 91%.

Further, the control unit 50 turns on the buzzer 71 when the output voltage ratio of the multi-rotation potentiometer 12 is 0% and 100%, and turns off the buzzer 71 when the output voltage ratio is more than 0% and less than 100%. and That is, the control unit 50 changes the sound generation state of the buzzer 71 when the electrical output of the multi-rotation potentiometer 12 satisfies a predetermined condition. As a specific example, the control unit 50 changes the buzzer 71 from the on state to the off state when the output voltage ratio of the multi-rotation potentiometer 12 changes from 0% to 1%. Further, the control unit 50 changes the buzzer 71 from the OFF state to the ON state when the output voltage ratio of the multi-rotation potentiometer 12 changes from 99% to 100%.

As a result, when the user rotates the knob 21 of the rotary dial 11, the light-emitting element 68 turns red in the section where the number displayed on the scale portion 23 is [000], that is, in the section between the terminal Ecw and the terminal Eccw. Along with lighting, the buzzer 71 is turned on. In addition, in the sections where the numbers displayed on the scale portion 23 are [more than 000, 100 or less] and [more than 900, 999 or less], the light emitting element 68 lights yellow and the buzzer 71 is turned off. In addition, in the section where the numbers displayed on the scale portion 23 are [more than 100 and 900 or less], the light-emitting element 68 is lit in white and the buzzer 71 is turned off.

Therefore, when the illumination light 63 of the light-emitting element 68 irradiated to the scale portion 23 turns red and the buzzer 71 sounds, the user who rotates the knob 21 can set the electric output of the multi-rotation potentiometer 12 to It can be recognized that the output voltage ratio based on is 0% or 100%. In addition, when the illumination light 63 of the light emitting element 68 irradiated to the scale portion 23 turns yellow, the user determines that the output voltage ratio based on the electrical output of the multi-rotation potentiometer 12 is more than 0% and 10% or less, or It can be recognized that it has become more than 90% and less than 100%. In addition, the user should confirm that the output voltage ratio based on the electrical output of the multi-rotation potentiometer 12 is more than 10% and less than or equal to 90% when the illumination light 63 of the light emitting element 68 irradiated to the scale portion 23 turns white. You can recognize that you are in range.

As described above, according to the potentiometer-equipped dial 10 having the rotary dial 11 according to the present embodiment, even while the user is turning the knob 21, the electric output of the multi-rotation potentiometer 12 is a predetermined value or a predetermined value. The user can be made to recognize that the range has been reached without reading the display contents of the scale portion 23. - 特許庁As a result, for example, when the adjustment range to be adjusted by the user by turning the knob 21 is the output voltage ratio of more than 10% and 90% or less, the user can determine the color of the illumination light 63 irradiated to the scale 23. At the timing when the color changes from white to yellow, it can be recognized that the color is out of the adjustment range. In addition, when the user starts rotating the knob 21 in a situation where the color of the illumination light 63 is yellow, the color of the illumination light 63 applied to the scale portion 23 is switched from yellow to white. While recognizing that the rotation direction of the knob 21 is correct, it can be recognized that the rotation direction of the knob 21 is wrong by switching the color of the illumination light 63 from yellow to red. Therefore, it is possible to prevent the user from wasting time due to an erroneous operation, and to efficiently rotate the knob 21 .

In the example shown in FIG. 18, the lighting color of the illumination light 63 is red for both the terminal Ecw in the CW direction and the terminal ECcw in the CCW direction. can be changed. This allows the user who rotates the knob 21 to determine whether the output voltage ratio of the multi-rotation potentiometer 12 is 0% or 100%. Similarly, by changing the lighting color of the illumination light 63 when the output voltage ratio of the multi-rotation potentiometer 12 is more than 0% and less than 10% and when it is more than 90% and less than 100%, the user can adjust the multi-rotation potentiometer It is possible to determine whether the output voltage ratio of 12 is in the range of more than 0% and 10% or less or in the range of more than 90% and less than 100%. Also, with regard to the sound of the buzzer 71, by changing the type of sound when the output voltage ratio of the multi-rotation potentiometer 12 is 0% and when it is 100%, the user can see that the output voltage ratio of the multi-rotation potentiometer 12 is , 0% or 100%.

In the example shown in FIG. 18, when the knob 21 is rotated, light emission is performed so that the color of the illumination light 63 is changed and the tone generation state of the buzzer 71 is changed at the terminal (Ecw, Eccw) and the vicinity of the terminal when the knob 21 is rotated. Device parameters and buzzer parameters are set, but these parameters can be arbitrarily set by changing the above program. Therefore, if the output voltage ratio corresponding to the display content (three-digit number) of the scale section 23 to be finally adjusted by rotating the knob 21 is, for example, 45%, the section of 43% or more and less than 47% is selected. The light-emitting element parameter may be set so that the white lighting section is set and the sections of 40% to 43% and 47% to 50% are yellow lighting sections. In this manner, the light-emitting element parameters are set so that the color of the illumination light 63 changes in the electric output of the multi-rotation potentiometer 12 corresponding to the display contents of the scale section 23 to be finally adjusted and in the vicinity thereof. Thus, the user can recognize that the rotation angle of the knob 21 has approached the target rotation angle without reading the display contents of the scale portion 23 . Therefore, the turning operation of the knob 21 can be performed more efficiently. The above points apply not only to the light-emitting element parameters but also to the buzzer parameters.

<Modifications, etc.>
The technical scope of the present invention is not limited to the above-described embodiments, but also includes forms with various modifications and improvements within the range where specific effects obtained by the constituent elements of the invention and their combinations can be derived.

For example, in the above embodiment, the number of digits displayed on the scale portion 23 is three digits, but the number of digits on the scale portion 23 may be more or less than three digits. Moreover, the characters displayed on the scale portion 23 are not limited to numbers, and may be alphabetic characters, symbols, or a combination of a plurality of types of characters. Further, the scale display method may be either digital or analog. Further, the scale portion 23 may be any one that changes the display content according to the rotation angle of the knob 21 .

Further, in the above embodiment, the scale portion 23 is provided separately from the knob 21, but the present invention is not limited to this, and the scale portion may be provided integrally with the knob. When the scale portion 23 is provided separately from the knob 21 as in the above embodiment, the scale portion 23 is not hidden by the finger of the user rotating the knob 21. Therefore, the illumination light emitted to the scale portion 23 There is an advantage that the user can easily perceive the 63 colors.

In the above-described embodiment, the illumination light 63 emitted by the light emitting element 68 of the illumination unit 30 is irradiated onto the scale portion 23. However, the portion irradiated with the illumination light 63 is not limited to the scale portion. 23 may be present. Specifically, for example, a window portion (not shown) whose color is changed by irradiation with the illumination light 63 may be provided near the scale portion 23 and the illumination light 63 may be applied to the window portion. In other words, the portion irradiated with the illumination light 63 may be a portion within the visual field of the user who rotates the knob 21 .

In the above-described embodiment, the rotary dial and the rotary potentiometer are combined to form a dial with a potentiometer. is not limited.

In the above embodiment, the electric output of the potentiometer changes linearly according to the rotation angle of the knob. A wave output or the like may be used.

In the above embodiment, the illumination light 63 has three colors (yellow, white, and red), but the types and number of colors of the illumination light 63 can be changed arbitrarily. For example, as the rotation angle of the knob 21 approaches the terminal Ecw or the terminal Eccw, the color of the illumination light 63 may be changed in two steps, three steps, or more steps. Thereby, the user can recognize how close the rotation angle of the knob 21 is to the terminal Ecw or the terminal Eccw by the change in the color of the illumination light 63 .

Further, in the above-described embodiment, as a specific aspect of changing the sounding state of the buzzer 71, the sounding state of the buzzer 71 is switched between the sounding state and the non-sounding state, but the present invention is not limited to this. , the type of sound emitted by the buzzer 71 may be changed. The types of sound can be classified by, for example, continuous sound, intermittent sound, pitch of intermittent sound, volume, sound quality, pitch, and the like. Also, the volume of the buzzer 71 may be changed as the rotation angle of the knob 21 approaches the terminal Ecw or the terminal Eccw. Thereby, the user can recognize how close the rotation angle of the knob 21 is to the terminal Ecw or the terminal Eccw by the change in the volume of the buzzer 71 .

Further, in the above-described embodiment, the color of the illumination light 63 is changed as a specific aspect of changing the irradiation state of the illumination light 63. However, the illumination light 63 is not limited to this, and the illumination light 63 is provided when a predetermined condition is satisfied. (the light emitting element 68 emits light), and in other cases, the illumination light 63 may not be emitted. For example, the light emitting element 68 may be lit when the output voltage ratio of the multi-rotation potentiometer 12 is 0% and 100%, and the light emitting element 68 may be extinguished otherwise. Alternatively, the light-emitting element 68 may be turned on when the electrical output of the multi-rotation potentiometer 12 approaches a target value, and the light-emitting element 68 may be turned off otherwise.

Moreover, in the above-described embodiment, a configuration including both the illumination unit 30 and the buzzer 71 is employed, but a configuration including only one of the illumination unit 30 and the buzzer 71 may be employed.

10... Dial with potentiometer, 11... Rotating dial, 12... Multi-rotating potentiometer, 21... Knob, 23... Scale part, 30... Illuminating part, 47... Illuminating substrate, 49... Transparent plate, 50... Control part (notification part), 52... Mask plate, 63... Illumination light, 68... Light emitting element, 71... Buzzer, 76... Convex part

A dial with a potentiometer according to the present invention includes a knob that is rotated by a user, a scale portion that allows the user to read the display content, and the display content of the scale portion by transmitting the rotational force of the knob due to the rotation operation to the scale portion. A rotating dial having a variable transmission mechanism, and a shaft rotating integrally with the knob, outputting an electrical signal corresponding to the rotation angle of the shaft, and an electrical output value that is the output value of the electrical signal. a potentiometer that changes according to the rotation angle of the shaft , and a notification unit that notifies the user that the value of the electric output of the potentiometer has satisfied a preset condition.
Also, a rotary dial according to the present invention is used for the dial with a potentiometer.

Claims (8)

a rotary dial having a knob that is rotated by a user and a scale that changes display content according to the rotation angle of the knob;
a potentiometer that outputs an electrical signal corresponding to the rotation angle of the knob;
a notification unit that notifies a user that the electrical output of the potentiometer has satisfied a predetermined condition;
A dial with a potentiometer. The rotary dial further has an illumination unit that illuminates the scale or its vicinity,
2. The dial with a potentiometer according to claim 1, wherein the notification unit changes the illumination state of the illumination light when the electrical output of the potentiometer satisfies the predetermined condition. The illumination unit is configured to be able to change the color of the illumination light,
The dial with a potentiometer according to claim 2, wherein the notification unit changes the color of the illumination light as the illumination state of the illumination light. Equipped with a buzzer that emits sound,
The dial with a potentiometer according to any one of claims 1 to 3, wherein the notification unit changes the sounding state of the buzzer when the electrical output of the potentiometer satisfies the predetermined condition. The dial with a potentiometer according to any one of claims 1 to 3, wherein the scale portion is provided separately from the knob. The scale section has a mask plate for reading the display content, and a transparent plate overlaid on the mask plate,
The illumination unit has an illumination substrate arranged over the mask plate so as to be adjacent to the transparent plate, and a light emitting element mounted on the illumination substrate,
3. The dial with a potentiometer according to claim 2, wherein the light emitting element irradiates the illumination light in a direction perpendicular to the thickness direction of the illumination substrate. The transparent plate has a convex portion,
The dial with a potentiometer according to claim 6, wherein the illumination section irradiates the convex portion with the illumination light. A knob for rotation operation,
a scale part whose display content changes according to the rotation angle of the knob,
A rotary dial configured to be mountable with a potentiometer that outputs an electrical signal corresponding to the rotation angle of the knob,
A rotary dial comprising a notification unit for notifying a user that the electrical output of the potentiometer has satisfied a preset condition.

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