JP5210059B2 - Operating device - Google Patents

Description

  The present invention relates to an operating device capable of performing a multifunctional operation with a small number of operation units.

  The vehicle air conditioner operating device includes a temperature setting mode switching operation unit for adjusting the temperature in the vehicle, an air volume setting mode switching operation unit for adjusting the air flow into the vehicle, and a wind direction for adjusting the air outlet into the vehicle. And a setting mode switching operation section. And these switching operation parts are each comprised by the dial knob which can be rotated. In addition to the switching operation unit, the operation device includes an operation unit including a switch for operating and stopping the air conditioner and an on / off switch for operating and stopping the compressor.

  Operation units such as dial knobs and switches can be downsized to some extent. However, most of the passengers who actually operate the operating device are drivers. Therefore, when the operation unit is downsized, it is not preferable because the driver needs to change the viewpoint several times during driving in order to confirm the position. On the contrary, a larger one is preferable. However, when three dial knobs and a plurality of switches are mounted, the operating device becomes large and the appearance deteriorates.

In view of this, Japanese Patent Application Laid-Open No. 2004-228561 provides an operating device that is configured to change the switching of each setting mode by a push switch and that can change the selection item in the setting mode selected by one dial knob.
JP 2006-199199 A

  However, in the operation device of Patent Document 1, it is necessary to change the selection item by reaching (changing) the dial knob after operating the push switch to change the mode. For this reason, when changing the selection item of one setting mode, it is necessary to confirm the positions of the two switches.

  The present invention has been made in view of conventional problems, and an object of the present invention is to provide an operating device that can be reduced in size as a whole and has good operability.

In order to solve the above problems, an operating device according to the present invention is an operating device that includes two or more setting modes having a plurality of selection items, selects a predetermined setting mode, and selects a predetermined selection item. A dial knob disposed so as to be rotatable and movable along the axial direction of the rotation center, a rotation operation detecting means for detecting a rotation direction and an amount of rotation of the dial knob, and an axis of the dial knob A pushing position detecting means for detecting a moving position along the direction, and changing to a predetermined setting mode set in advance among a plurality of setting modes according to the moving position of the dial knob detected by the pushing position detecting means; , and a changing means for changing the selected item in the setting mode selected in response to the rotational operation of the dial knob detected by the rotation operation detecting means, said die The knob is held on the substrate on which the pushing position detecting means is disposed so as to be rotatable and movable in the axial direction. The base is fixed to the substrate and holds the dial knob, and the dial knob is mounted on the substrate. And a ball member disposed between an end of the spring and the substrate, and a holder for restricting separation of the dial knob from the substrate .

  According to this operation device, the dial knob is provided so as to be rotatable and movable in the axial direction, and a predetermined setting mode can be selected from among a plurality of setting modes depending on the movement position of the dial knob in the axial direction. In this state, the selected item in the selected setting mode can be changed by rotating the dial knob. Therefore, not only the number of dial knobs but also the number of push switches for selection can be reduced. As a result, the overall size can be reduced, and the degree of freedom in design can be improved. In addition, when changing the selection item in the predetermined setting mode, it is only necessary to confirm the position of the dial knob once, so that the operability can be greatly improved.

  The operating device includes a base portion that holds the dial knob, a spring that biases the dial knob in a direction away from the substrate, a ball member disposed between the spring and the substrate, and a separation of the dial knob. The dial knob can be rotated and advanced and retracted in a stable state. Further, when the dial knob is loaded in the axial direction and moved to the second movement position pushed from the advanced first movement position, when the load is released, the dial knob is moved to the first movement position by the biasing force of the spring. Return. Therefore, the convenience can be further improved by assigning the first movement position to a setting mode that is likely to be frequently used.

In this operating device, the pushing position detecting means includes an electric electrode generated by a change in a distance between the movable electrode fixed to the dial knob, a fixed electrode provided at a position opposed to the movable electrode, and the movable electrode and the fixed electrode. It is preferable to include a detection circuit that detects the change position of the dial knob in a non-contact state between the movable electrode and the fixed electrode by detecting a change.
  The operating device of the present invention is an operating device that includes two or more setting modes having a plurality of selection items, selects a predetermined setting mode, and selects a predetermined selection item, and can be rotated. And a dial knob arranged to be movable along the axial direction of the center of rotation, a rotation operation detecting means for detecting the rotation direction and the rotation amount of the dial knob, and movement along the axial direction of the dial knob. A pushing position detecting means for detecting a position, and changing to a predetermined setting mode set in advance among a plurality of setting modes according to the movement position of the dial knob detected by the pushing position detecting means, and detecting the rotation operation Change means for changing a selection item in the setting mode selected according to the rotation operation of the dial knob detected by the means, and the pushing position detection means An annular push detection movable contact portion fixed to the opening end of the dial knob, a push detection fixed contact portion provided at a position opposite to the push detection movable contact portion, the push detection movable contact portion, and the push A pressing operation detection circuit for detecting a pressing position of the dial knob in a non-contact state by detecting an electrical change between the detection fixed contact portion, and the rotation operation detecting means includes an opening of the dial knob. A rotation detection movable contact portion provided at a predetermined interval in the circumferential direction from the end, a rotation detection fixed contact portion provided at a predetermined interval in the circumferential direction at a position opposite to the rotation detection movable contact portion, and the rotation detection movable A rotation operation detection circuit that detects a rotation direction and an amount of rotation of the dial knob in a non-contact state by detecting an electrical change between the contact portion and the rotation detection fixed contact portion. It may be.
  As described above, by adopting a configuration in which the movable electrode and the fixed electrode are not in contact with each other, it is possible to eliminate the physical action for detecting the pushing position. Therefore, it is possible to operate the dial knob smoothly and to improve reliability and durability because there is no contact portion.

In this case, the gripping portion of the dial knob is a conductive portion that can be electrically connected to the movable electrode, and the detection circuit can detect the contact state of the human body and the electrical change input through the fixed electrode. It is preferable to detect a non-contact state. In this way, it is possible to prevent the selection item from being changed even if the dial knob rotates due to the application of vibration or an unintended physical external force. And since it is not necessary to provide a complicated electric circuit and power supply in the movable electrode side for comprising in this way, it can be comprised simply.

  This operating device is particularly effective when applied to change the setting of the air conditioner of the vehicle. In other words, it has a temperature setting mode for adjusting the temperature inside the vehicle, an air volume setting mode for adjusting the air flow into the vehicle, and an air direction setting mode for adjusting the air outlet into the vehicle. The operation device of the air conditioner that performs air conditioning preferably has the above-described configuration.

  In this case, in the configuration in which the dial knob is held at the first movement position by the urging force of the spring, the setting mode that can be changed at the first movement position is either the auto mode or the manual mode as in the temperature setting mode. It is preferable to set to what is used. In addition, the setting mode that can be changed at the second movement position is when the auto mode is selected, such as the air volume setting mode for adjusting the air flow into the vehicle or the air direction setting mode for adjusting the air outlet into the vehicle. It is preferable to set the frequency of use very low.

  In the operating device of the present invention, the predetermined setting mode can be selected from among a plurality of setting modes in accordance with the axial movement position of one dial knob, and the dial knob can be operated while the predetermined setting mode is selected. By rotating, the selected item in the selected setting mode can be changed. Therefore, since the number of dial knobs as well as the number of mode selection push switches can be reduced, the overall size can be reduced, and the degree of design freedom can be improved. In addition, when changing the selection item in the predetermined setting mode, it is only necessary to confirm the position of the dial knob once, so that the operability can be greatly improved.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, an operation device 10 according to an embodiment of the present invention is arranged at, for example, a lower part of a liquid crystal panel 1 mounted on an instrument panel of a vehicle, and has two or more setting modes having a plurality of selection items. Is for changing the setting mode and selection items of the air conditioner equipped with

  First, a vehicle air conditioner includes a cooling cycle in which refrigerant discharged from a compressor flows to an outside heat exchanger, a pressure reducing valve, and an inside heat exchanger, an inside heat exchanger, a pressure reducing valve, and an outside heat exchange. And a heating cycle that flows to the vessel. The cooling cycle and the heating cycle are switched by operating the four-way valve by the operation of the operating device 10 of the present invention. In addition, the temperature adjustment in the vehicle, the adjustment of the air flow into the vehicle, and the change of the air outlet into the vehicle can be similarly switched by operating the operation device 10.

  Moreover, the liquid crystal panel 1 displays the setting state of the operation of the air conditioner by the operation of the operation device 10 of the present invention. The liquid crystal panel 1 is provided with a temperature setting display unit 2 indicating a set temperature which is a selection item of the temperature setting mode on the upper side. Below this temperature display section, there is provided a wind direction setting display section 3 showing a blower outlet (direction) which is a selection item of the wind direction setting mode. Below the wind direction setting display unit 3, there is provided an air volume setting display unit 4 that indicates the amount of air blown from the air outlet, which is a selection item of the air volume setting mode. The right side of the wind direction setting display unit 3 shows a selection state of an auto mode in which the wind direction setting and the air volume setting are automatically changed based on the detection value of the sensor in the vehicle, and a manual mode in which the setting is manually changed by an occupant. A change setting display unit 5 is provided.

  And the operating device 10 of this embodiment changes the auto mode and manual mode which are the functions of an air conditioner. Further, the temperature setting mode, the wind direction setting mode, and the air volume setting mode are used to select a predetermined setting mode and change a plurality of selection items set in advance in each setting mode to predetermined items. is there.

  Specifically, the operating device 10 according to the first embodiment includes five switches 11 to 15 and one dial knob 16.

  Each of the switches 11 to 15 is a normally open push switch in which a pair of contacts are brought into contact with each other by a pressing operation, and the contacts are separated by releasing the pressing operation. Among them, the ON switch 11 located at the top is for starting the operation of the air conditioner. The lower off switch 12 is for stopping the operation of the air conditioner. The lower air conditioner switch 13 is for changing the driving and stopping of the compressor in order. The lower auto switch 14 is for setting the control of the air conditioner to an automatic auto mode. The mode switch 15 below it is for changing the selection item of the wind direction setting mode. Specifically, when the state before the operation is the auto mode, the mode switch 15 is changed to the manual mode by the operation, and the selection item of the wind direction setting mode is changed to the item next to the selection item before the operation. To do. When the state before the operation is the manual mode, the manual mode is maintained by the operation, and the selection item of the wind direction setting mode is changed to the item next to the selection item before the operation.

  As shown in FIG. 2A, the dial knob 16 is mounted so as to be externally fitted to a base portion 32 fixed to a printed circuit board 27, and its outer peripheral portion is restricted by a holder 34 so that it cannot be detached. Thus, it can be rotated with respect to the printed circuit board 27 and can be moved along the axial direction of the center of rotation. Then, the direction and amount of rotation of the dial knob 16 are detected by a microcomputer 42 described later, and the selection items of the temperature setting mode or the air volume setting mode are changed via the microcomputer 42. Further, the moving position along the axial direction of the dial knob 16 is detected by the microcomputer 42, and the setting mode for changing the selection item is changed to either the temperature setting mode or the air volume setting mode.

  Specifically, the dial knob 16 is made of a resin having a cylindrical shape with a lower end opening, and a movable electrode portion 17 is provided at the opening end. The movable electrode portion 17 is provided in a state of being fixed to the dial knob 16 by performing conductive plating on the surface of the resin. Specifically, as shown in FIG. 2 (B), the movable electrode portion 17 includes a rotation detecting movable contact portion 18 provided at a predetermined interval in the circumferential direction from the opening end, and an annular push-down formed of the opening end surface. And a movable contact point 19 for detection. Among them, the rotation detecting movable contact portion 18 is provided with six projecting pieces 20 protruding outward in the radial direction, and is provided at the tip of each projecting piece 20. Moreover, the outer peripheral part of this dial knob 16 comprises the holding part 21 for a passenger | crew to perform rotation operation. The gripping portion 21 is a conducting portion that is conductively plated on the surface to enable electrical conduction to the movable electrode portion 17.

  Further, the dial knob 16 is provided with a pair of urging means arrangement portions 22 at positions facing the opening end surface. The urging means disposing portion 22 extends in a circular shape from the opening end surface toward the closed end, and urges the dial knob 16 in a direction away from the printed circuit board 27 inside. A spring 23 and a ball member 24 positioned between the end of the spring 23 and the substrate are disposed. A separate rotor 25 is disposed inside the dial knob 16. The dial knob 16 and the rotor 25 can be rotated together by engagement of a slide groove 48 provided on the inner peripheral portion of the dial knob 16 and a convex portion 49 provided on the outer peripheral portion of the rotor 25. And it is attached so that movement along the axial direction of the rotation center of the dial knob 16 is possible. The rotor 25 is provided with a locking claw portion 26 projecting radially inward at an opening end thereof.

  As shown in FIG. 2C, the printed circuit board 27 includes a fixed electrode portion 28 provided at a position facing the movable electrode portion 17 of the dial knob 16. The fixed electrode portion 28 includes a plurality of rotation detection fixed contact portions 29A1 to 29A6, 29B1 to 29B6, 29C1 to 29C6 provided at a predetermined interval in the circumferential direction, and an indentation detection fixed contact that is formed inside these Part 30. That is, in the present embodiment, three rotation detection fixed contact portions 29A1, 29B1, 29C1 to 29A6, 29B6, 29C6 are provided for the six rotation detection movable contact portions 18, respectively. The printed circuit board 27 is provided with a pair of holder fixing holes 31.

  The base portion 32 is made of a resin having a cylindrical shape with a lower end opening. A screw hole extending in the axial direction is formed on the opening end surface of the outer peripheral portion, and is fixed to the printed circuit board 27 by screwing. is there. A locking groove 33 is provided on the outer peripheral portion of the open end of the base portion 32 so as to form a step shape. The locking claw portion 26 of the rotor 25 is locked in the locking groove 33 in a state where the dial knob 16 is assembled. Thereby, the rotor 25 is held so as to be rotatable with respect to the base member 32 and not movable in the axial direction. Accordingly, the dial knob 16 that rotates integrally with the rotor 25 is rotatably held by the base member 32 via the rotor 25.

  The holder 34 includes a surface covering portion 35 that covers the surface of the protruding piece 20 of the dial knob 16, and a side surface covering portion 36 that protrudes so as to cover the side surface of the protruding piece 20 from the outer edge of the surface covering portion 35. It is a circular ring. The side cover portion 36 of the holder 34 is provided with a pair of fixing pieces 37 that penetrate the holder fixing holes 31 of the printed circuit board 27. Then, the surface covering portion 35 of the holder 34 is engaged with the protruding piece 20 of the dial knob 16 so that the dial knob 16 is restricted from moving outward along the axial direction with respect to the base member 32. .

  Thus, the dial knob 16 mounted via the base portion 32, the rotor 25 and the holder 34 is held by the base portion 32 via the rotor 25, and the protruding piece 20 by the surface covering portion 35 of the holder 34. The coating holds the printed circuit board 27 in a rotatable manner. Further, the dial knob 16 is biased to the first movement position separated from the printed circuit board 27 by the biasing force of the spring 23 via the ball member 24. Further, when the dial knob 16 is pressed toward the printed circuit board 27, the dial knob 16 is guided by the outer peripheral surface of the rotor 25, and approaches the axial direction that is the center of rotation against the urging force of the spring 23. The second movement position can be moved. When the pressing is released, the spring 23 is moved from the second movement position to the first movement position by the urging force of the spring 23, and the outward movement is restricted at a predetermined position by the holder 34. In the first movement position, a predetermined gap S (for example, 0.3 mm) is formed between the movable electrode portion 17 of the dial knob 16 and the fixed electrode portion 28 of the printed circuit board 27, and the non-contact state is maintained. .

  The printed circuit board 27 is connected to a separate control board (not shown). As shown in FIG. 3, the control board includes a first rotation operation detection circuit 38 connected to the rotation detection fixed contact portions 29A1 to 29A6 and a second connection connected to the rotation detection fixed contact portions 29B1 to 29B6. A rotation operation detection circuit 39, a third rotation operation detection circuit 40 connected to the rotation detection fixed contact portions 29C1 to 29C6, and a push operation detection circuit 41 connected to the push detection fixed contact portion 30 are mounted. Yes. The control board is provided with each mechanism (drive component) constituting the liquid crystal panel 1 and the air conditioner based on the operation of the switches 11 to 15 and the operation of the dial knob 16 detected through the detection circuits 38 to 41. A microcomputer 42 is mounted as a control unit for controlling.

  Each of the detection circuits 38 to 41 includes a comparator 44 (EXOR circuit) connected in parallel to an oscillator 43 as shown in FIG. The rotation detection fixed contact portions 29A1 to 29A6 are connected to the input portion Y of the comparator 44 of the first rotation operation detection circuit 38. Further, rotation detection fixed contact portions 29B1 to 29B6 are connected to the input portion Y of the comparator 44 of the second rotation operation detection circuit 39. Further, rotation detection fixed contact portions 29C1 to 29C6 are connected to the input portion Y of the comparator 44 of the third rotation operation detection circuit 40. In addition, a pressing contact fixed contact 30 is connected to the input Y of the comparator 44 of the pressing operation detection circuit 41. Further, an integrating circuit 45 for converting a plurality of waveforms into a constant voltage value that can be read by the microcomputer 42 is connected to the output section Z of the comparator 44.

  The microcomputer 42 includes the rotation detection movable contact portion 18, the rotation detection fixed contact portions 29A1 to 29A6, 29B1 to 29B6, 29C1 to 29C6, and the rotation operation detection circuits 38 to 40, and the rotation direction of the dial knob 16. It also serves as a rotation operation detecting means for detecting the rotation amount. In addition, the push detection movable contact portion 19, the push detection fixed contact portion 30, and the push operation detection circuit 41 serve as a push position detection means for detecting the movement position of the dial knob 16 along the axial direction. . Furthermore, according to the movement position of the dial knob 16 detected via the push operation detection circuit 41, the microcomputer 42 can change the selection item (temperature setting) of the temperature setting mode at the non-movement position, specifically, The air volume setting mode selection item (air volume setting) can be changed at the pushed-in position, and the temperature setting mode or the air volume setting is made according to the rotation direction and the rotation amount of the dial knob 16 detected via the rotation operation detection circuits 38 to 40. It serves as a change means for changing the mode selection item.

  Next, the action of contact detection, rotation detection, and push-in detection of the dial knob 16 by the microcomputer 42 will be specifically described.

  First, the voltage from the oscillator 43 is input to the comparator 44. When the human body is not touching the dial knob 16, the same square wave is input to any of the input portions XY of the comparator 44 as shown in FIG. Accordingly, the inputs at both input sections match (on / on or off / off), and the output from the output section Z of the comparator 44 becomes an off signal (0 V). As a result, there is no output from the integrating circuit 45 to the microcomputer 42.

  Then, as shown in FIG. 5B, when the human body touches the dial knob 16, the rotation detecting movable contact portion 18 constituting the movable electrode portion 17 and the push detection are detected by the gripping portion 21 on which conductive plating is applied. The movable contact portion 19 is electrically connected to the human body. In this state, the rotation detection fixed contact portion 29 and the push detection fixed contact portion 30 constituting the fixed electrode portion 28 of the printed circuit board 27 facing the rotation detection movable contact portion 18 and the push detection movable contact portion 19 are: Equivalent to the state of being grounded through the human body. Thereby, the capacitance of the input unit Y of the comparator 44 is increased, and the rising and falling of the square wave input to the input unit Y are delayed. As a result, the output waveform from the output unit Z of the comparator 44 is a square wave having a short period corresponding to the delay. The integration circuit 45 converts the output into a constant voltage value and outputs it to the microcomputer 42. As a result, the microcomputer 42 can detect whether the human body is in contact with the presence or absence of the input of this signal.

  When the dial knob 16 is rotated clockwise, the rotation detecting movable contact portion 18 constituting the movable electrode portion 17 is rotated clockwise. Accordingly, the rotation detection fixed contact portions 29A1 to 29A6, the rotation detection fixed contact portions 29B1 to 29B6 and the rotation detection fixed contact portions 29C1 to 29C6 facing the rotation detection movable contact portion 18 are sequentially switched. That is, as described above, the rotation operation detection circuits 39, 39, and 40 to which the rotation detection fixed contact portions 29A1 to 29A6, 29B1 to 29B6, and 29C1 to 29C6 facing the rotation detection movable contact portion 18 are connected to the microcomputer. In order to output signals to 42, signals are input to the microcomputer 42 in the order of the rotation operation detection circuits 38, 39, and 40. Conversely, when the dial knob 16 is rotated counterclockwise, signals are input in the order of the rotation operation detection circuits 40, 39, and 38. Therefore, the rotation direction of the dial knob 16 can be detected by the order in which signals are input. Further, the operation (rotation) amount can be detected by the number of inputs from the same rotation operation detection circuits 38 to 40.

  Further, when the dial knob 16 is pushed in, as shown in FIG. 5C, the movable electrode portion 17 is conducted to the human body as in the case where the human body touches the dial knob 16, and the fixed electrode portion of the printed circuit board 27 is connected. This is equivalent to a state in which the 28 pressing detection fixed contact portions 30 are grounded via the human body. In addition, since the gap S between the movable electrode portion 17 and the fixed electrode portion 28 is reduced, the capacitance of the input portion Y of the comparator 44 of the push-in operation detection circuit 41 is further increased. As a result, the rising and falling of the square wave input to the input unit Y are further delayed. As a result, the signal input from the integrating circuit 45 to the microcomputer 42 becomes larger than when the human body touches the dial knob 16. Therefore, the microcomputer 42 can detect whether or not the dial knob 16 is in the depressed state based on the magnitude of the input signal.

  Thus, according to the configuration of the present embodiment, the microcomputer 42 detects an electrical change in the distance (gap S) between the movable electrode portion 17 and the fixed electrode portion 28 via the detection circuits 38 to 41, and Whether or not a human body is touching the dial knob 16 can be detected by the presence or absence of the input. Further, the rotation direction and the rotation amount of the dial knob 16 can be detected based on the input order and the input number of the rotation operation detection circuits 38 to 40. Further, it is possible to detect whether or not the dial knob 16 is pushed in based on the strength of the signal input from the pushing operation detection circuit 41.

  In this embodiment, a threshold value for determining the strength of the input signal is stored in the memory 46 which is a storage unit. When the input signal is lower than the threshold value, that is, when the dial knob 16 is not depressed, the set temperature of the temperature setting mode that accepts the change in both the auto mode and the manual mode is changed. When the input signal is higher than the threshold value, that is, when the dial knob 16 is depressed, the selection item of the air volume setting mode that is changed only in the manual mode is changed.

  Next, the control by the microcomputer 42 will be specifically described.

  First, when the start operation of the air conditioner is performed by operating the on switch 11, the microcomputer initializes each data stored in the memory 46 in step S1. Here, the initialization resets all data such as a standby time (for example, 10 msec) for detecting operations of the switches 11 to 15 and the dial knob 16. Also, the previous control content is read from the memory 46, and control is started under the same conditions. That is, when the previous control condition is the auto mode, the control is started in the auto mode, and when the previous control condition is the manual mode, the control is started with the selection item (setting condition) at that time. .

  Next, in step S2, the process waits until the standby time elapses. When the standby time elapses, the switch operation determination process in step S3 and the dial operation determination process in step S4 are performed in parallel. When these operation determination processes are completed, the control contents are determined and stored in the memory 46 based on the determined operations of the switches 11 to 15 and the dial knob 16 in step S5, and then the control contents are determined in step S6. Is output to the air conditioner and the liquid crystal panel 1.

  Next, the switch operation determination process in step S3 will be specifically described.

  If the operation of the on switch 11 is detected in step S3, since the control of the air conditioner has already been executed, it is determined that the operation is erroneous and the operation is not accepted. Further, when the operation of the off switch 12 is detected, the control of the air conditioner is stopped. When the operation of the air conditioner switch 13 is detected, the operation is performed when the compressor is not operated, and the operation is stopped when the compressor is operated. When the operation of the auto switch 14 is detected, the auto mode is continued when the control is executed in the auto mode, and the control is changed to the auto mode when the control is executed in the manual mode. To do. Further, when the operation of the mode switch 15 is detected, when the control is executed in the auto mode, the mode is changed to the manual mode and the wind direction is changed, and when the control is executed in the manual mode, the manual mode is changed. Continue the mode and change the wind direction.

  Next, the dial operation determination process in step S4 will be specifically described.

  In this dial operation determination process, as shown in FIG. 7, the microcomputer 42 first reads a connection port with the push-in operation detection circuit 41 in step S4-1 and compares the input signal Vcom with a threshold value. If the input signal Vcom is greater than or equal to the threshold value, the process proceeds to step S4-2, the setting mode to be changed is changed to the air volume setting mode, and the process proceeds to step S4-4. If the input signal Vcom is less than the threshold value, the process proceeds to step S4-3, the setting mode to be changed is changed to the temperature setting mode, and the process proceeds to step S4-4.

  In step S4-4, the connection port with the rotation operation detection circuits 38 to 40 is read and the direction of the detection order is determined. When the order of the first rotation operation detection circuit 38, the second rotation operation detection circuit 39, and the third rotation operation detection circuit 40 is reached, the process proceeds to step S4-5, and the rotation operation detection circuit 38˜ The operation amount is determined based on the number of signals input from 40, and the process proceeds to step S4-9. If the detection order is different, the process proceeds to step S4-6.

  In step S4-6, if the direction of the detection order is the order of the third rotation operation detection circuit 40, the second rotation operation detection circuit 39, and the first rotation operation detection circuit 38, the process proceeds to step S4-7. Then, the operation amount is determined by down-counting, and the process proceeds to step S4-9. If the detection order is different, the process proceeds to step S4-8, where it is determined that the direction is undefined, that is, the dial knob 16 is not rotated, and the process proceeds to step S4-9.

  In step S4-9, the count number is determined and stored in the memory 46. Then, in step S4-10, the dial position determination for associating the count number with each setting condition is performed, and the process returns.

  Next, the transition of the liquid crystal panel 1 by the dial operation determination process in step S4 will be described.

  For example, when the air conditioner is controlled in the auto mode and the dial knob 16 is not operated, the liquid crystal panel 1 is a display in a normal state located at the upper center of FIG. In this state, when the dial knob 16 is rotated clockwise (S4-3 → S4-5) without being pushed in, the set temperature in the temperature setting mode is raised by 1 ° C. as shown on the upper right side of FIG. Further, when the dial knob is rotated counterclockwise (S4-3 → S4-7) without being pushed in, the set temperature in the temperature setting mode is lowered by 1 ° C. as shown in the upper left side of FIG.

  On the other hand, when the dial knob 16 is pushed in the normal state at the upper center of FIG. 8 (S4-2), as shown in the lower center of FIG. 8, the air volume setting display unit 4 in the air volume setting mode and the auto mode are displayed. The change setting display unit 5 indicating the selected state is displayed, and the temperature setting display unit 2 and the wind direction setting display unit 3 are turned off. In this state, when the pressing operation of the dial knob 16 is stopped, the normal state at the upper center is restored. In other words, the present embodiment is configured such that the change from the auto mode to the manual mode is not performed only by pressing the dial knob 16.

  Further, when the dial knob 16 is pushed in and further rotated clockwise (S4-2 → S4-5), the change setting display section 5 is changed to the manual mode as shown in the lower right middle of FIG. In addition, the air volume setting in the air volume setting mode is increased by one level. When the pressing operation of the dial knob 16 is stopped in this state, as shown at the lower right end, the temperature setting display unit 2 and the wind direction setting display unit 3 are turned on again, and the setting is confirmed (step S5).

  Further, when the dial knob 16 is pushed in and further rotated counterclockwise (S4-2 → S4-7), the change setting display section 5 changes to the manual mode as shown in the lower left middle side of FIG. At the same time, the air volume setting in the air volume setting mode is lowered by one level. When the pressing operation of the dial knob 16 is stopped in this state, as shown at the lower left end, the temperature setting display unit 2 and the wind direction setting display unit 3 are turned on again, and the setting is confirmed (step S5).

  In the above example, after the set temperature is changed by 1 ° C., the operation of the dial knob 16 is stopped to confirm the setting. However, the amount of rotation operation of the dial knob 16 is increased, and the set temperature is set to 2 ° C. It is also possible to stop the operation of the dial knob 16 after changing the temperature by 3 ° C. or more and confirm the setting at that temperature. Of course, this also applies to the air volume setting mode.

  As described above, in the operation device 10 according to the present embodiment, the dial knob 16 is provided so as to be rotatable and movable in the axial direction, and a predetermined setting mode among a plurality of setting modes is changed depending on the axial movement position of the dial knob 16. The configuration is selected as possible. Then, the selected item in the selected setting mode is changed by rotating the dial knob 16 in this setting mode selection state. Therefore, not only the number of dial knobs 16 but also the number of switches for selection can be reduced. As a result, the overall size can be reduced, and the degree of freedom in design can be improved. In addition, after changing the setting mode, when the selection item in the setting mode is subsequently changed, it is only necessary to confirm the position of the dial knob 16 once, so that the operability can be greatly improved. it can.

  In the present embodiment, the movable electrode portion 17 and the fixed electrode portion 28 are held in a non-contact state, and the pushing (second movement) position can be detected by a change in electric capacitance therebetween. Further, smooth operation of the dial knob 16 can be realized by eliminating the physical contact action. In addition, since it is possible to prevent a decrease in electrical detection accuracy due to damage due to friction, reliability and durability can be improved. Further, since it is not necessary to provide a complicated electric circuit or power source on the movable electrode side, it can be easily configured. In addition, when no electrical change occurs, the microcomputer 42 cannot detect the operation, so that the selection item is changed even when the dial knob 16 rotates due to vibration or unintended physical external force. Can be prevented.

  Further, in the present embodiment, the first moving position where the dial knob 16 is separated from the printed circuit board 27 is likely to be frequently used, and the temperature setting mode used in both the auto mode and the manual mode is set. Assigned to change. In addition, the air volume setting in the air volume setting mode in which the dial knob 16 adjusts the air flow into the vehicle, which is used less frequently when the auto mode is selected, is changed so that the second air movement position close to the printed circuit board 27 is selected. Assigned to. As a result, the operability of the occupant can be improved.

  9 and 10 show a modification of the operating device 10 according to the first embodiment. As shown in FIG. 9, this modification is different from the first embodiment in that the setting mode for changing the selection item when the dial knob 16 is pressed is a wind direction setting mode for changing the outlet. . The switch 15 ′ located at the lower end is configured to change the air volume setting mode instead of the air direction setting mode. In this modification, the microcomputer 42 controls the same as in the first embodiment.

  When the air conditioner is controlled in the auto mode and the dial knob 16 is not operated, the liquid crystal panel 1 is a display in a normal state located at the upper center of FIG. In this state, when the dial knob 16 is rotated clockwise without being pushed in, the set temperature is raised by 1 ° C. as shown in the upper right side of FIG. 10, and when rotated counterclockwise, the upper left side of FIG. As shown, the set temperature is lowered by 1 ° C.

  On the other hand, when the dial knob 16 is depressed, the wind direction setting display unit 3 in the wind direction setting mode and the change setting display unit 5 indicating the selected state of the auto mode are displayed as shown in the lower center of FIG. The display unit 2 and the air volume setting display unit 4 are turned off.

  Then, when it is further rotated clockwise in this pushed state, the change setting display section 5 is changed to the manual mode as shown in the lower right middle side of FIG. 10, and the wind direction setting mode is set in advance. The mode is changed to the next mode in the set order. When the pressing operation of the dial knob 16 is stopped in this state, the temperature setting display unit 2 and the air volume setting display unit 4 are turned on again, as shown at the lower right end, and the setting is confirmed.

  In addition, when it is further rotated counterclockwise in the pushed state, the change setting display unit 5 is changed to the manual mode and the wind direction setting mode is set in advance as shown in the lower left middle of FIG. The mode is changed to the previous mode. When the pressing operation of the dial knob 16 is stopped in this state, as shown at the lower left end, the temperature setting display unit 2 and the air volume setting display unit 4 are turned on again, and the setting is confirmed.

  The modification of the first embodiment configured as described above can obtain the same operations and effects as the first embodiment.

  11 and 12 show the operating device 10 of the second embodiment. In the second embodiment, as shown in FIG. 11, the pushing state of the dial knob 16 can be detected in two stages, the wind direction setting mode can be changed in the pushing state in the first stage, and the second stage can be changed. This is largely different from the first embodiment in that the air volume setting in the air volume setting mode can be changed in the depressed state. In the second embodiment, it is preferable to provide a concavo-convex portion between the dial knob 16 and the rotor 25 so that the depressed state can be recognized by moderation. Similarly to the first embodiment, the microcomputer 42 pushes the dial knob 16 in the non-push position (second movement position) by one step according to the magnitude of the input signal from the push operation detection circuit 41. The third movement position is configured to be able to detect the first movement position pushed in two steps. Further, since the air volume setting mode and the air direction setting mode can be changed by the dial knob 16, the lower end switch 15 shown in the first embodiment is not provided.

  In the second embodiment, the air conditioner is controlled in the auto mode, and when the dial knob 16 is not operated, the liquid crystal panel 1 is a display in a normal state located at the upper center of FIG. In this state, when the dial knob 16 is rotated clockwise without being pushed in, the set temperature is raised by 1 ° C. as shown in the upper right side of FIG. 12, and when rotated counterclockwise, the upper left side of FIG. As shown, the set temperature is lowered by 1 ° C.

  Further, when the dial knob 16 is depressed by one step, as shown in the middle center of FIG. 12, the wind direction setting display unit 3 in the wind direction setting mode and the change setting display unit 5 indicating the selected state of the auto mode are displayed. The temperature setting display unit 2 and the air volume setting display unit 4 are turned off.

  Then, when rotating clockwise in this one-step pushing state, the change setting display unit 5 is changed to the manual mode and the wind direction setting mode is set as shown in the middle right part of FIG. The mode is changed to the next mode in the preset order. When the pressing operation of the dial knob 16 is stopped in this state, the temperature setting display unit 2 and the air volume setting display unit 4 are turned on again as shown in the middle right end, and the setting is confirmed.

  Further, when the counterclockwise rotation is performed in the one-step push-in state, the change setting display unit 5 is changed to the manual mode and the wind direction setting in the wind direction setting mode is set in advance as shown in the middle left middle of FIG. The mode is changed to the previous mode in the set order. When the pressing operation of the dial knob 16 is stopped in this state, the temperature setting display unit 2 and the air volume setting display unit 4 are turned on again as shown in the middle left end, and the setting is confirmed.

  Further, when the dial knob 16 is pushed in two steps, as shown in the lower center of FIG. 12, the air volume setting display unit 4 in the air volume setting mode and the change setting display unit 5 indicating the selected state of the auto mode are displayed. The temperature setting display unit 2 and the wind direction setting display unit 3 are turned off.

  Then, when rotating clockwise in this two-step pushing state, the change setting display section 5 is changed to the manual mode as shown in the lower right middle side of FIG. The level is raised. In this state, when the pressing operation of the dial knob 16 is stopped, the temperature setting display unit 2 and the wind direction setting display unit 3 are turned on again, as shown at the lower right end, and the setting is confirmed.

  Further, when the counterclockwise rotation is performed in the two-stage push-in state, the change setting display unit 5 is changed to the manual mode as shown in the lower left middle side of FIG. The level is lowered. When the pressing operation of the dial knob 16 is stopped in this state, the temperature setting display unit 2 and the wind direction setting display unit 3 are turned on again as shown in the lower left corner, and the setting is confirmed.

  The operation device 10 according to the second embodiment configured as described above can obtain the same operations and effects as those of the first embodiment, and can further reduce the number of installed switches.

  FIG. 13 shows the operating device 10 of the third embodiment. This third embodiment is greatly different from the first embodiment in that the pressing position of the dial knob 16 is detected by the on / off state of the mechanical push switch 52.

  As shown in FIG. 13A, the dial knob 16 is made of a resin having a cylindrical shape with a lower end opening. As in the first embodiment, the dial knob 16 of the third embodiment is provided with an urging means disposing portion 22, and a spring 23 and a ball member 24 are disposed therein. Further, the dial knob 16 of the present embodiment is provided with a switch operating portion 47 that protrudes inward from the center of the closed end portion. A separate rotor 25 is disposed inside the dial knob 16. The dial knob 16 and the rotor 25 can be rotated together by engagement of a slide groove 48 provided on the inner peripheral portion of the dial knob 16 and a convex portion 49 provided on the outer peripheral portion of the rotor 25. And it is attached so that movement along the axial direction of the rotation center of the dial knob 16 is possible.

  In the present embodiment, the movable electrode portion 17 as in the first embodiment is not provided on the dial knob 16 and the holding portion 21 is also subjected to conductive plating for enabling electrical conduction. It has not been. Instead, a flange portion 50 protruding radially outward is provided at the lower end of the rotor 25, and the lower surface of the flange portion 50 is a movable electrode portion for detecting rotation as shown in FIG. 13B. A movable contact portion 18 is provided. The rotor 25 is provided with a through hole 51 for allowing the switch operating portion 47 of the dial knob 16 to pass therethrough. Further, the ball member 24 disposed on the dial knob 16 is disposed so as to be positioned between the spring 23 and the flange portion 50.

  On the other hand, as shown in FIG. 13 (C), the printed circuit board 27 is disposed at a position opposite to the movable electrode portion 17 of the dial knob 16 so that rotation detection fixed contact portions 29A1 to 29A6, 29B1 to 29B6 and 29C1 are fixed electrode portions. ~ 29C6 are provided. Then, instead of the ring-shaped fixed contact portion for detecting push-in, the switch operating portion 47 is pressed so as to be positioned at the center, so that the pair of contacts come into contact with each other, and the contacts are separated by releasing the pressing operation. A normally open push switch 52 is provided. In FIG. 13C, a common contact portion 53 is provided at the same position as the indentation detecting fixed contact portion 30 of the first embodiment. The common contact portion 53 is located between the rotation detection fixed contact portions 29A1 to 29A6, 29B1 to 29B6, and 29C1 to 29C6 located on the radially outer side, and the opposed rotation detection movable contact portion 18 is located. Thus, conduction is possible, and a signal is output to the microcomputer 42.

  The base portion 32 is different from the first embodiment in that the locking groove 33 is not provided on the outer peripheral portion. Similarly to the first embodiment, the holder 34 includes a surface covering portion 35 and a side surface covering portion 36, and a fixing piece 37 is provided on the side surface covering portion 36.

  In the dial knob 16 of the third embodiment configured as described above, the push switch 52 is maintained in the OFF state in the non-pressed state. In this state, the rotation operation of the dial knob 16 is performed by the rotation detecting movable contact portion 18, the rotation detecting fixed contact portions 29A1 to 29A6, 29B1 to 29B6, 29C1 to 29C6, and the common contact portion 53 as in the first embodiment. When detected in the same manner, the set temperature in the temperature setting mode for accepting the change in either the auto mode or the manual mode is increased or decreased according to the rotation direction.

  Further, when the occupant pushes the dial knob 16, the push switch 52 is turned on. In this state, when a rotation operation of the dial knob 16 is detected, the selection item of the air volume setting mode or the air direction setting mode is changed according to the rotation direction.

  The operating device 10 of the present invention is not limited to the configuration of the above embodiment, and various modifications can be made.

  For example, in the third embodiment, since it is configured with only one push switch 52, only the first movement position and the second movement position can be detected, but by arranging two or more switches, It is also possible to detect two or more moving positions. In this way, the three setting modes can be changed with one dial knob 16 as in the second embodiment.

  Moreover, although the said embodiment demonstrated and demonstrated the case where the operating device 10 of this invention changed the setting condition of the vehicle air conditioner as an example, it is not restricted to a vehicle air conditioner, It can apply to various apparatuses. It is possible, and the same action and effect can be obtained regardless of the application.

It is a front view which shows the state which applied the operating device of 1st Embodiment which concerns on this invention to the vehicle air conditioner. (A) is sectional drawing of an operating device, (B) is a bottom view of a dial knob, (C) is a top view of a printed circuit board. It is a block diagram which shows the structure of an operating device. It is a block diagram which shows the structure of the operation detection circuit of FIG. (A), (B), (C) are graphs showing input / output waveforms of the operation detection circuit. It is a flowchart which shows the control by a microcomputer. It is a flowchart which shows the dial operation determination process of FIG. It is the schematic which shows the transition of the liquid crystal panel by a dial operation determination process. It is a front view which shows the modification of 1st Embodiment. It is the schematic which shows the transition of the liquid crystal panel of the modification by dial operation determination processing. It is a front view which shows the state which applied the operating device of 2nd Embodiment to the vehicle air conditioner. It is the schematic which shows the transition of the liquid crystal panel of 2nd Embodiment by dial operation determination processing. (A) is sectional drawing of the operating device of 3rd Embodiment, (B) is a bottom view of a rotor, (C) is a top view of a printed circuit board.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Liquid crystal panel 2-5 ... Display part 10 ... Operation apparatus 11-15 ... Switch 16 ... Dial knob 17 ... Movable electrode part 18 ... Movable contact part for rotation detection (rotation operation detection means)
19 ... Movable contact part for pushing detection (pushing position detecting means)
DESCRIPTION OF SYMBOLS 21 ... Holding part 23 ... Spring 24 ... Ball member 25 ... Rotor 27 ... Printed circuit board 28 ... Fixed electrode part 29A-29C ... Fixed contact part for rotation detection (rotation operation detection means)
30 ... Fixed contact portion for pressing detection (pressing position detecting means)
32 ... Base part 34 ... Holder 38-40 ... Rotation operation detection circuit (rotation operation detection means)
41 ... Push operation detection circuit (push position detection means)
42 ... Microcomputer (rotating operation detecting means, pushing position detecting means, changing means)

Claims (4)

An operating device having two or more setting modes having a plurality of selection items, selecting a predetermined setting mode, and selecting a predetermined selection item,
A dial knob that can be rotated and moved along the axial direction of the rotation center;
A rotation operation detecting means for detecting a rotation direction and a rotation amount of the dial knob;
A pushing position detecting means for detecting a moving position along the axial direction of the dial knob;
According to the movement position of the dial knob detected by the push-in position detection means, the setting operation mode is changed to a predetermined setting mode set in advance among a plurality of setting modes, and the rotation operation of the dial knob detected by the rotation operation detection means Change means for changing the selected item in the setting mode selected according to
Equipped with a,
The dial knob is held so as to be rotatable and movable in the axial direction on a substrate on which the pushing position detecting means is disposed.
A base portion fixed to the substrate and holding the dial knob;
A spring for urging the dial knob in a direction away from the substrate;
A ball member disposed between the end of the spring and the substrate;
A holder for regulating separation of the dial knob from the substrate;
Operating device, characterized in that it comprises a. The pushing position detecting means includes
A movable electrode fixed to the dial knob;
A fixed electrode provided at a position facing the movable electrode;
A detection circuit for detecting a pressing position of the dial knob in a non-contact state by detecting an electrical change caused by a change in a distance between the movable electrode and the fixed electrode;
The operating device according to claim 1, further comprising: An operating device having two or more setting modes having a plurality of selection items, selecting a predetermined setting mode, and selecting a predetermined selection item,
A dial knob that can be rotated and moved along the axial direction of the rotation center;
A rotation operation detecting means for detecting a rotation direction and a rotation amount of the dial knob;
A pushing position detecting means for detecting a moving position along the axial direction of the dial knob;
According to the movement position of the dial knob detected by the push-in position detection means, the setting operation mode is changed to a predetermined setting mode set in advance among a plurality of setting modes, and the rotation operation of the dial knob detected by the rotation operation detection means Change means for changing the selected item in the setting mode selected according to
Equipped with a,
The indentation position detecting means includes an annular indentation detection movable contact portion fixed to an opening end of the dial knob, an indentation detection fixed contact portion provided at a position opposite to the indentation detection movable contact portion, and the indentation A pressing operation detection circuit that detects a pressing position of the dial knob in a non-contact state by detecting an electrical change between the movable contact portion for detection and the fixed contact portion for detection of pressing; and
The rotation operation detecting means includes a rotation detection movable contact portion provided at a predetermined interval in the circumferential direction from the opening end of the dial knob, and a rotation provided at a predetermined interval in the circumferential direction at a position opposed to the rotation detection movable contact portion. The rotation direction and the rotation amount of the dial knob are detected in a non-contact state by detecting an electrical change between the detection fixed contact portion, the rotation detection movable contact portion, and the rotation detection fixed contact portion. A rotation operation detection circuit;
An operating device characterized by that. The grip part of the dial knob is a conduction part capable of electrical conduction to the movable electrode,
The operation device according to claim 2 , wherein the detection circuit detects a contact state and a non-contact state of a human body by an electrical change input through a fixed electrode.

Images