KR20020020332A - Rotary switch assembly without a contact point - Google Patents

Abstract

PURPOSE: A contactless rotary switch assembly is provided to previously prevent the short of a circuit due to a rotary switch and the contact failure of the rotary switch as well as maintain the absolute position of the rotary switch by improving the structure of the rotary switch. CONSTITUTION: The rotary switch assembly(100) comprises a movable unit(20) rotated by a knob(10), and a fixed unit(30) corresponding to the movable unit. The fixed unit(30) consists of a plurality of light emission parts(31) which emit lights with time difference and are disposed on a same line with predetermined gaps, and one light receiving part(32) which is branched to be corresponding to respective light emission parts. The movable unit(20) is mounted to be slid under a contactless state between the light emission parts(31) and the branches(32b) the light receiving part(32), thereby generating unit powers different from each other while selectively blocking the light from the light emission part.

Description

Rotary switch assembly without a contact point

The present invention relates to a rotary switch assembly, and more particularly, to a rotary switch assembly in which a movable unit moved by rotation of an axis and a fixed unit fixed to correspond to the movable unit generate a phase difference by mutual contact. .

In general, the rotary switch 1 is used to select one of a plurality of choices, as shown in FIG. 1, and has a circumferential contact 1a that is not a simple button type. It is for selecting a desired contact by rotating the movable unit provided with the wiper 1b on the fixed unit having a.

In other words, taking advantage of the characteristics of the rotary encoder that converts the mechanical analog change amount into a digital amount, the microcomputer detects and controls the number of pulses that change according to the left and right rotation amounts, and performs a specific function mode. There is a trend that is widely used in such products.

However, when the rotary switch 1 is applied to a device using water or using steam, the following problems occur.

First, the contacts 1a of the fixed unit are shorted with each other by water, and there is a concern that a fire is generated.

That is, as the contact points 1a arranged at a predetermined interval are shorted together, the resistance value becomes "0", and an overload is applied to the electronic / electric components (not shown) electrically connected to the rotary switch 1. In particular, the overload of a switch or a transistor that changes a resistance value is severe, and each component burns. Therefore, a topic may be generated due to overload.

Second, the contact 1a of the fixed unit and the wiper 1b of the movable unit are oxidized by water, and thus the contact between the fixed unit and the wiper of the movable unit is lost, thereby preventing contact with each other.

Third, in a device using water, such as a washing machine, or steam, such as a microwave oven, a circuit board 2 coated with a waterproof coating solution 3 is generally used. (1a, 1b) causes contact failure between the fixed unit and the movable unit.

That is, when water flows into the circuit board 2, a plurality of electrical components (resistors, transistors, etc.) mounted on the circuit board may be shorted to each other. In order to prevent this, The coating liquid 3 made of urethane or the like is applied to the upper and lower surfaces of the circuit board. However, the coating liquid 3 flows into the gap of the rotary switch 1 composed of a plurality of parts, and is fixed to the contact portions 1a and 1b of the rotary switch, thereby wiping the rotary switch due to the interference of the coating liquid. (12) A problem arises in which the virtual contact with the contact point 1a is not made, and thus the consumer cannot select a function mode to select.

On the other hand, the rotary switch has the following problems.

As shown in FIGS. 2 and 3, the rotary switch 1 has a signal having a directionality caused by a time difference between the contact A and the contact B generated during rotation, and the contact 1a and the wiper 1b contact each other. Only the pulse signal generated when the microcomputer is recognized by the microcomputer. Therefore, when the rotary switch is stopped, the signal having the directionality is not generated, and thus the initial state of the rotary switch is in a state where the microcomputer cannot recognize the current position of the rotary switch. At this time, the initial mode no longer detects the function mode selected by the rotary switch.

That is, once the rotary switch 1 is stopped, the signal having a directionality is no longer generated, and thus the microcomputer is in an initial state, and even if the rotary switch is rotated again, the function mode currently in progress is not recognized by the microcomputer. Not only does it determine whether it is a mode, it can also interfere with the selection of the function mode for the next step.

In particular, a device equipped with a display device, even though the function mode selected by the rotary switch should be displayed among various function modes, when the rotary switch is stopped, the microcomputer is in an initial state to generate a display signal to be sent to the display device. As it becomes impossible to know what function mode is currently in progress.

The present invention has been made to solve the problems of the prior art, by improving the structure of the rotary switch, to prevent the short circuit of the circuit by the rotary switch and the contact failure of the rotary switch in advance, the absolute position of the rotary switch is Its purpose is to be maintained.

1 is a cross-sectional view showing the structure of a rotary switch according to the prior art.

2 is a plan view showing the structure of the fixing unit of FIG.

Figure 3 is a schematic circuit diagram of a rotary switch and a microcomputer according to the prior art.

4 is a cross-sectional view showing the structure of a rotary switch according to the present invention.

5 is an exploded perspective view illustrating the wheel shape of FIG. 4, respectively.

6 is a cross-sectional view taken along line II of FIG. 4.

7 is a diagram showing that the unit output generated by the rotation of the rotary switch according to the present invention variously appears according to a predetermined angle.

8 is a schematic circuit diagram of a light emitting device, a light receiving device, and a microcomputer according to the present invention;

Explanation of symbols for main parts of the drawings

10: knob 20: movable unit

21: wheel 21a: first wheel

21b: second wheel 21c: third wheel

22: axis 23: groove

30: fixed unit 31: light emitting unit

31a: light emitting element 31b: supporter

32: light receiving unit 32a: light receiving element

32b: optical path 100: rotary switch

In order to achieve the above object, the present invention is a rotary switch assembly provided with a movable unit that is moved by the rotation of the knob, and a fixed unit fixed to correspond to the movable unit, the fixing unit is timed with each other to light And a plurality of light emitting parts diverging and positioned at a predetermined interval on the same line, and a light receiving part branched to correspond to the light emitting parts to receive the light emitted from each light emitting part. The unit is provided to be movable in a contactless state between the light emitting portion and the branch of the light receiving portion, so that different unit outputs for selecting a function mode are provided while selectively blocking or passing the light of the light emitting portion when the knob is rotated. And a contactless rotary switch assembly characterized in that it is generated.

Referring to the drawings to describe the above content in more detail as follows.

Figure 4 is a cross-sectional view showing the structure of a rotary switch according to the invention, Figure 5 is an exploded perspective view showing the wheel shape of Figure 4, Figure 6 is a cross-sectional view of the I-I of Figure 4, Figure 7 is in accordance with the present invention FIG. 8 is a diagram illustrating various unit outputs generated by rotation of a rotary switch according to a predetermined angle. FIG. 8 is a schematic circuit diagram of a light emitting device, a light receiving device, and a microcomputer according to the present invention.

The rotary switch assembly 100 of the present invention, as shown in Figure 4, is provided with a movable unit 20, which is moved by the rotation of the knob 10, and a fixed unit 30 fixed to correspond to the movable unit In the rotary switch assembly, the fixing unit 30 emits light with a time difference from each other, and receives a plurality of light emitting parts 31 positioned at a predetermined interval on the same line and the light emitted from the light emitting parts. It consists of a light receiving unit 32 branched to correspond to each of the light emitting unit, and the movable unit 20, while the knob rotates to selectively block or pass the light of the light emitting unit to select the function mode It is provided so as to be movable between the branch of the light emitting portion and the light receiving portion so that different unit output (state value obtainable according to the rotation angle of the movable unit) for generating.

In this case, the light emitting unit 31 includes a light emitting element 31a which emits light directly, and a supporter which surrounds the circumference of the light emitting element to protect the light emitting element from water and to hold the position of the light emitting element. And 31b.

In addition, the light receiving unit 32 receives one light of the light emitting elements 31a selectively by the movable unit 20 and transmits the unit output to a microcomputer 40 of FIG. 8. 32a, and an optical path 32b branched according to the number of light emitting elements so as to transmit the light of each light emitting element to the light receiving elements.

Here, the optical path 32b is preferably made of an optical fiber.

And, the movable unit 20, between the branch of the light emitting element and the light receiving portion 32 to block or pass the light of the light emitting element 31a as shown in Figs. It is composed of a cylindrical wheel (wheel) 21 located in the, and the shaft 22 is provided in the center of the wheel to rotate the wheel.

In addition, at least one groove 23 is formed at the circumference of the wheel so that light passes or is blocked by the circumference of the cylindrical wheel 21. Alternatively, at least one transparent material portion may be provided to allow light to pass through the circumference of the wheel instead of the groove.

In addition, the present invention increases the number of the wheel 21, in order to select the various functional mode by increasing the number of different unit outputs, the number of the light emitting element (31a) in accordance with the increased number of wheels The same is increased, and the number of grooves 23 formed in the wheel circumference is also increased.

At this time, the wheels 21 of which the number is increased are located on mutually concentric circles so as to rotate together about the axis 22, and mutually positioned so as to be located between the branches of the light emitting element 31a and the light receiving part 32, respectively. It is arranged at a predetermined interval.

In addition, the number of the grooves 23 formed in the circumference of the wheel is increased by a series of equal ratios having a value of azeotropy 2 as the number of the wheels 21 increases one by one. The length of the circumference of the groove is made equal to each other and the length of the circumference of each groove formed in one wheel is also made the same.

One embodiment of the wheel 21 of the rotary switch assembly made as described above is as follows.

Wheel 21 according to an embodiment, as shown in 5 and 6, when the starting point S is 0 degrees, grooves are formed in the circumferential surface so that light passes through the circumference corresponding to 0 to 180 degrees Cylindrical first wheel 21a, cylindrical second wheel 21b having grooves formed on the circumference thereof so that light passes through the circumference corresponding to 0 to 90 degrees and the circumference corresponding to 180 to 270 degrees And the light passes through the circumference corresponding to 0 to 45 degrees, the circumference corresponding to 90 to 135 degrees, the circumference corresponding to 180 to 225 degrees, and the circumference corresponding to 270 to 315 degrees. It consists of the cylindrical 3rd wheel 21c in which the groove was formed in the circumferential surface.

An embodiment of the wheel made as described above performs the following role.

As shown in FIGS. 6 to 8, three light emitting elements 31a emit light with a time difference, and one light receiving element 32a is a branched optical path 32b positioned to correspond to the light emitting elements, respectively. The light is received through. At this time, when the shaft 22 rotates, a groove of the first wheel 21a, the second wheel 21b, and the third wheel 21c is located at a branch of the light emitting element 31a and the light receiving unit 32. When all of them are located, the light of each light emitting device that is diverged with a time difference is obtained through the grooves through the time difference and is obtained with a time difference to the light receiving element 32a, even though there is only one light receiving element. It is acceptable to obtain the unit output (1, 1, 1). When the shaft rotates continuously, the grooves of the first wheel and the second wheel are positioned where the branch of the light emitting element and the light receiving unit are located, and the non-groove of the third wheel is positioned to diverge. As light of the light emitting device passes through only the grooves and is received by the light receiving device, unit outputs (1, 1, 0) can be obtained. In addition, as the axis rotation continues, the unit output (1,0,1), (1,0,0), (0,1,1), (0,1,0), (0,0,1), (0,0,0) can be obtained.

Here, the unit output is a state value that can be obtained according to the rotation angle of the axis, and is a kind of signal that can be sent to the microcomputer 40 to recognize specific function modes, and "1" indicates light of the light emitting element 31a. It means that the light is transmitted to the light receiving element (32a), "0" means that the light of the light emitting element is blocked by the non-groove portion around the wheel.

The various unit outputs as described above have unique values of different function modes, so that each time the rotary switch rotates the rotary switch by a predetermined range, the function modes that can be selected by the user are different, respectively, based on the reference coordinate S. The unit output of the microcomputer (40 of FIG. 8) can recognize the unit output of the stopped position even if the rotary switch is stopped by taking different state values, so that the next step and the customer can easily proceed to the desired step. Can be done.

That is, the rotary switch is placed in an absolute position from which the function mode corresponding to the unit outputs (1, 1, 1) can be selected until the rotary switch is rotated 45 degrees with the reference point S as the starting point. When rotated by 90 degrees, the rotary switch is in an absolute position to select a function mode corresponding to the unit outputs (1, 1, 0), and such a function mode selection opportunity can be obtained at 45 degree intervals. After stopping the rotary switch, the unit output corresponding to the position can be continuously transmitted to the microcomputer, and when the rotary switch is rotated again, the starting point starts again at the stopped position instead of the S point as the reference table. Function modes of the next stage can be easily selected, and the functional modes skipped 2 and 3 can be selected if necessary, thereby making it possible to easily use the functional modes of electronic products (especially washing machines) that are complicated.

On the other hand, the wheel 21 according to the present invention may take only three, as in the embodiment, may take more than, may take less than. If the four wheels are taken, the first wheel, the second wheel, the third wheel, and the fourth wheel are provided, and the number of grooves formed in each wheel is increased by the equivalence sequence of azeotropic 2. Therefore, when the groove of the first wheel is one, the groove of the fourth wheel, which is the outermost wheel, is eight. In addition, according to the above description, the number of unit outputs is 16.

That is, the rotary switch having four wheels can be used in an apparatus equipped with sixteen functional modes.

So far, the present invention has been described with reference to the preferred embodiments, and those skilled in the art to which the present invention pertains to the detailed description of the present invention and other forms of embodiments within the essential technical scope of the present invention. Could be implemented. Herein the essential technical scope of the present invention is shown in the claims.

As described above, the present invention is a switch for selecting a function mode using a light having a non-contact structure, the light receiving element, the light emitting element and the wheel by using a non-contact by transmitting a mutual signal to each other, as in the prior art (In this case, the contact part is made of a material such as copper, which is an electrical conductor.) The contact part oxidation by water and the contact part short are not generated at all.

And since the rotary switch of the present invention is a contactless structure, even if the waterproof coating liquid flows into the rotary switch, as in the prior art, there is no problem of contact failure caused by the coating liquid being deposited on the contact point of the rotary switch.

Meanwhile, the present invention may generate various unit outputs, and thus may have unique values of different function modes. Therefore, each time the consumer rotates the rotary switch of the present invention by a predetermined range, the function modes that can be selected are different, and each unit output takes absolute coordinates based on S, which is a reference coordinate, so that the rotary switch is stopped. The microcomputer can recognize the unit output of the stationary position, so that the next stage and the stage desired by the consumer can be easily performed.

In other words, when the rotary switch is rotated again, the starting point can be easily selected as the next step function mode as the starting point is restarted at the stopped position instead of the S point which is the reference table. The choice makes it easier to access the functional modes of electronic products, such as washing machines, which are becoming more complex.

In addition, the present invention can implement a rotary switch that can select a plurality of functional modes by increasing the number of wheels, it can be easily applied to a device having a large number of functional modes.

On the other hand, when a device using a general optical signal is provided with light-emitting elements, the light-receiving elements are provided at the corresponding positions, and the number thereof is the same, whereas the present invention includes a plurality of light-emitting elements according to the number of wheels. Even if only one light receiving element is provided, since there is no obstacle in implementing the present invention, it is possible to reduce the cost and component cost according to the circuit configuration. In addition, since the circuit configuration is simplified and the number of parts is reduced, the defects generated in the process can be significantly reduced, thereby improving the reliability of the product.

In addition, it includes all the effects mentioned in the detailed description of the invention.

Claims (11)

In the rotary switch assembly provided with a movable unit which is moved by the rotation of the knob, and a fixed unit corresponding to the movable unit, The fixed unit is; A plurality of light emitting parts which emit light with a time difference from each other and are positioned at a predetermined interval on the same line, and one light receiving part which is divided to correspond to each of the light emitting parts to receive the light emitted from each light emitting part; Made up of The movable unit; It is provided to be movable in a non-contact state between the light emitting portion and the branch of the light receiving portion, so that different unit output for the selection of the function mode is generated while selectively blocking or passing the light of the light emitting portion when the knob rotates. Solid state rotary switch assembly characterized in that. The method of claim 1, The light emitting unit; A light emitting element that emits light directly; A solid state rotary switch assembly comprising a supporter surrounding the light emitting element to protect the light emitting element from water and to hold the position of the light emitting element. The method of claim 1, The light receiving unit; One light receiving element selectively receiving the light of each light emitting element by the movable unit and transferring the unit output to a microcomputer; And a light path branched according to the number of light emitting devices so as to transmit the light of each light emitting device to the light receiving devices. The method of claim 3, wherein The optical path is a contactless rotary switch assembly, characterized in that made of optical fibers. The method of claim 1, The movable unit; A cylindrical wheel positioned between a branch of the light emitting element and the light receiving unit to block or pass light of the light emitting element; The contactless rotary switch assembly, characterized in that formed in the center of the wheel made of an axis for rotating the wheel. The method of claim 5, And forming at least one groove in a circumference of the cylindrical wheel to allow light to pass through the groove or to block light by a circumference in which the groove is not formed. The method of claim 5, And at least one portion of the cylindrical wheel periphery as a transparent material to allow light to pass through the transparent material or to block light by a perimeter that is not provided with the transparent material. The method of claim 5, In order to select various functional modes by increasing the number of different unit outputs, the number of wheels is increased, and the number of the light emitting elements is equally increased according to the number of wheels that are increased. Solid state rotary switch assembly, characterized by an increased number of grooves. The method of claim 8, And the wheels having increased numbers are disposed on mutually concentric circles so as to rotate together about the axis, and are disposed at predetermined intervals so as to be positioned between the light emitting portion and the branch of the light receiving portion, respectively. The method of claim 8, The number of grooves formed in the circumference of the wheel is increased in the same ratio sequence having a value of azeotropy 2 as the number of wheels increases by one, and the circumference of the groove and the length of the circumference of the uneven groove are equal And a circumferential length of each groove formed in one wheel is made equal to each other. The method according to claim 9 or 10, The wheel; When the starting point is 0 degrees, the cylindrical first wheel with a groove formed in the circumference so that light passes through the circumference corresponding to 0 degrees to 180 degrees, A cylindrical second wheel having a groove formed in the circumference thereof so that light passes through the circumference portion corresponding to 0 degrees to 90 degrees and the circumference portion corresponding to 180 degrees and 270 degrees; Circumference surface through which light passes through the circumference corresponding to 0 to 45 degrees, the circumference corresponding to 90 to 135 degrees, the circumference corresponding to 180 to 225 degrees, and the circumference corresponding to 270 to 315 degrees Solid state rotary switch assembly, characterized in that consisting of a third cylindrical wheel grooved.