JP2015101321A - Operation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an operation device capable of simplifying a structure thereof and saving space therein.SOLUTION: An operation device 100 includes the following which are incorporated inside a body 1: a belt member 24 or belt members 33 with protrusions driven by the operation of an operator in a bottom operation opening part 11 and in side operation opening parts 12; pulley members (a first pulley member 23, a second pulley member 32, and a third pulley member 42) which include at least two fulcrum parts (a first fulcrum part 231, a second fulcrum part 232 and a third fulcrum part 233; a fourth fulcrum part 321 and a fifth fulcrum part 322; and a sixth fulcrum part 421 and a seventh fulcrum part 422) around which the belt member 24 or the belt members 33 with protrusions are wound; and a plurality of belt type operation mechanisms(a first belt type operation mechanism 2, a second belt type operation mechanism 3, and a third belt type operation mechanism 4) which control a controlled member by driving the belt member 24 or the belt members 33 with protrusions.

Description

  The present invention relates to an operating device used for operating various devices such as a vehicle air conditioner and audio.

  Conventionally, for example, a dial rotation type, a lever slide type, a push switch type, and the like are used to operate a vehicle air conditioner.

  For example, Patent Document 1 discloses an operation device that, when a dial is rotated, rotates a shaft integrally and drives an inner wire of a cable as a cable driving member rotates.

JP 2003-54245 A

However, in the conventional operating device, the transmission mechanism that transmits the operating force of the dial or lever rotates around the fulcrum to drive the inner wire of the cable. A space for rotating the transmission mechanism is required.
In addition, in the type of operation device that slides the lever, it is necessary to secure the arm length of the lever, and further, there is a problem that it is difficult to save space because a movement area of the lever is necessary.

  The present invention is to provide an operating device capable of simplifying the structure and saving space.

  The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, it is not limited to this.

  The invention of claim 1 includes a body (1) in which an operation opening (11, 12) is formed, and a belt member (24) incorporated in the body and driven by an operation of the operator in the operation opening. 33), and a pulley member (23, 32, 42) around which the belt member is wound and including at least two fulcrum portions (231, 232, 233, 321, 322, 421, 422), An operating device (100) comprising a plurality of belt-type operating mechanisms (2, 3, 4) that control a controlled member by driving a belt member.

  According to a second aspect of the present invention, in the operating device according to the first aspect, the belt-type operating mechanism (2) and the other belt-type operating mechanism (3) among the plurality of belt-type operating mechanisms are: One of the fulcrum parts (232, 321) is arranged on a different axis, and the other fulcrum part (231, 322) is arranged on the same axis (C1). (100).

  The invention according to claim 3 is the operation device according to claim 1 or 2, wherein at least one of the belt-type operation mechanisms (3, 4) is operated by an operator. One of the fulcrum parts (321, 421) rotates about the axis (C1, C2) of the other fulcrum part (322, 422), and detects the rotation of the fulcrum part (36). Is an operating device (100) characterized by further comprising:

  According to a fourth aspect of the present invention, in the operating device according to any one of the first to third aspects, the pulley member (23, 32, 42) is on the front surface facing the operator in the use state. An operating device (100) comprising a display unit (25, 37, 47) for displaying the function of the controlled member.

  According to a fifth aspect of the present invention, in the operating device according to any one of the first to fourth aspects, the belt-type operating mechanism (2) is connected to the controlled member, and the belt member (24 ), And the pulley member (23) is arranged so that the belt member is driven by an operator's operation in the operation opening (11). The operation device (100) is characterized by being arranged so as to have an angle (r1) in the linear movement direction.

  According to the present invention, the following effects can be achieved.

(1) According to the invention of claim 1, a belt member incorporated in the body and driven by an operator's operation in the operation opening, and a pulley including at least two fulcrum portions around which the belt member is wound A plurality of belt-type operation mechanisms having members and controlling the controlled member by driving the belt member are provided.
As a result, a plurality of functions of the controlled member can be controlled and the operation of the operator is transmitted to the controlled member by driving the belt member, so that the operation mechanism for transmitting the operation of the operator to the controlled member can be made thin. The depth dimension of the operating device can be shortened.
Moreover, since another member can be arrange | positioned in the space enclosed by two fulcrum parts and a belt member, the space in an operating device can be used effectively. Therefore, simplification of the structure and space saving can be achieved.

(2) According to the invention of claim 2, in one belt-type operation mechanism and another belt-type operation mechanism, one fulcrum portion is disposed on a different axis and the other fulcrum is on the same axis. Arranged.
Thereby, in the two belt type operation mechanisms, the width dimension of the operation device can be shortened as compared with the case where the fulcrum portions are arranged at different positions. Therefore, simplification of the structure and space saving can be achieved.

(3) According to the invention of claim 3, in the at least one belt-type operation mechanism, one fulcrum portion rotates around the axis of the other fulcrum portion by the operation of the operator. And a detection part detects rotation of a fulcrum part.
Thereby, in one belt type operation mechanism, in addition to the control of the controlled member by the operation of driving the belt member, the controlled member can be controlled by the operation of rotating the fulcrum portion. That is, two functions of the controlled member can be controlled by one belt type operation mechanism. Therefore, simplification of the structure and space saving can be achieved.

(4) According to invention of Claim 4, a pulley member has a display part which displays the function of a to-be-controlled member in the front surface which faces an operator in use condition.
As a result, the pulley member not only functions as a shaft of the belt member but also functions as a display unit, so that space can be saved. Therefore, simplification of the structure and space saving can be achieved.

(5) According to the invention of claim 5, the pulley member is arranged so as to have an angle in the linear movement direction of the control member with respect to the direction in which the belt member is driven by the operation of the operator at the operation opening. Has been.
Thereby, the control member can be moved in a linear movement direction of a predetermined angle with respect to this direction, not limited to the direction in which the belt member is driven by the operation of the operator. That is, the controlled member can be arranged at an arbitrary position, and the linear movement direction of the controlled member can be matched with the direction in which the controlled member is operated, so that the degree of freedom of the layout inside the operating device is improved. Therefore, the degree of freedom in layout can be improved while simplifying the structure and saving space.

It is a schematic perspective view which shows the operating device 100 which concerns on embodiment of this invention. It is the figure which looked at the inside of body 1 of operating device 100 concerning the embodiment from the front. It is the figure which looked at the 1st belt type operation mechanism 2 and the dial type operation mechanism 5 of the operating device 100 which concerns on the said embodiment shown in FIG. 2 from the front. It is AA 'sectional drawing of the operating device 100 of the said embodiment shown in FIG. It is the figure which looked at the 2nd belt type operating mechanism 3, the 3rd belt type operating mechanism 4, and the dial type operating mechanism 5 of the operating device 100 which concerns on the said embodiment shown in FIG. 2 from the front. It is a functional block diagram of the control part 7 which concerns on the said embodiment.

The best mode for carrying out the present invention will be described below with reference to the drawings.
(Embodiment)
FIG. 1 is a schematic perspective view showing an operating device 100 according to an embodiment of the present invention.
In addition, each figure shown below including FIG. 1 is the figure shown typically, and the magnitude | size and shape of each part are exaggerated suitably for easy understanding.
FIG. 2 is a view of the inside of the body 1 of the operating device 100 according to the embodiment as viewed from the front. In FIG. 2, only the outer shape of the body 1 is indicated by a broken line.
In the following description, specific numerical values, shapes, materials, and the like are shown and described, but these can be changed as appropriate.

The operation device 100 according to the present embodiment is used for operation of an air conditioning device of a vehicle. The body 1, a plurality of belt-type operation mechanisms incorporated in the body 1, and adjustment of the air flow rate of the air conditioning device. A dial-type operation mechanism 5 for controlling functions and a control unit 7 (see FIG. 6) are provided.
The plurality of belt-type operation mechanisms controls air conditioning equipment as controlled members (not shown). Specifically, the plurality of belt-type operation mechanisms include a first belt-type operation mechanism 2 that controls switching between the outside air introduction function and the inside air circulation function, and a second that controls the air outlet switching and the rear defroster ON / OFF function. A belt-type operation mechanism 3 and a third belt-type operation mechanism 4 that controls the temperature adjustment and the ON / OFF function of the air conditioner are provided.

  As shown in FIG. 1, the body 1 is formed in a box state having a space inside, and the front surface (front surface shown in FIG. 1) facing the operator and the left and right ends of the front surface (left and right ends shown in FIG. 1). ) And a bottom surface formed at the lower end of the front surface (the lower end shown in FIG. 1).

  On the bottom surface, in the vicinity of the front side edge, the first operation knob 21 of the first belt type operation mechanism 2 protrudes, and a bottom surface operation opening 11 having a long side in the left-right direction (left-right direction shown in FIG. 1) is formed. ing. That is, the bottom operation opening 11 is formed so that the first operation knob 21 of the first belt type operation mechanism 2 can slide in the left-right direction.

  On the left side surface, the second operation knob 31 of the second belt type operation mechanism 3 projects in the vicinity of the back surface (the back surface shown in FIG. 1), and has a long side in the up-down direction (up-down direction shown in FIG. 1). An operation opening 12 is formed. That is, the side operation opening 12 on the left side surface is formed so that the second operation knob 31 of the second belt type operation mechanism 3 can slide in the vertical direction.

  On the right side surface, in the vicinity of the back side, the third operation knob 41 of the third belt type operation mechanism 4 protrudes, and a side operation opening 12 having a long side in the vertical direction (the vertical direction shown in FIG. 1) is formed. ing. That is, the side operation opening 12 on the right side surface is formed so that the third operation knob 41 of the third belt type operation mechanism 4 can slide in the vertical direction.

  On the front surface, the upper end of a second pulley member 32 (to be described later) of the second belt type operation mechanism 3 protrudes in the vicinity of the upper left end, and a front operation opening 13 formed in an arc shape is formed. That is, the front operation opening 13 near the upper left end is formed so that the second pulley member 32 of the second belt type operation mechanism 3 can rotate.

  Further, on the front surface, an upper end of a third pulley member 42 (to be described later) of the third belt type operation mechanism 4 protrudes in the vicinity of the upper right end, and a front operation opening 13 formed in an arc shape is formed. That is, the front operation opening 13 near the upper right end is formed so that the third pulley member 42 of the third belt type operation mechanism 4 can rotate.

  Further, on the front surface, an operation knob 51 of the dial type operation mechanism 5 is disposed substantially at the center, and a display unit 25 of the first belt type operation mechanism 2 is disposed in the vicinity of the lower end.

FIG. 3 is a view of the first belt type operating mechanism 2 and the dial type operating mechanism 5 of the operating device 100 according to the embodiment shown in FIG. 2 as viewed from the front.
In FIG. 3, only the outer shape of the body 1 is indicated by a broken line.

  The first belt type operation mechanism 2 includes a first operation knob 21, a control member 22, a first pulley member 23, and a belt member 24.

  The first operation knob 21 has a base end fixed to the belt member 24, protrudes downward from the bottom surface operation opening 11 (see FIG. 1) of the body 1, is gripped by the operator, and is parallel to the front surface of the body 1 ( It is configured to be linearly movable in the left and right direction shown in FIG.

  The control member 22 is connected to a controlled member (not shown). Specifically, the control member 22 includes a wire connection part 221, an inner wire 222 and an outer wire 224 that constitute the control wire 223, and a support part 225 that fixes an end of the outer wire 224 of the control wire 223 to a predetermined position of the body 1. Is provided.

  The wire connecting portion 221 has a proximal end fixed to the belt member 24 and moves by an operation of linearly moving the first operation knob 21 of the operator in a direction parallel to the bottom surface of the body 1 (left and right direction shown in FIG. 2). Following the member 24, it is configured to be linearly movable in a direction inclined by an angle r1 with respect to a direction parallel to the bottom surface of the body 1.

  The inner wire 222 is slidably inserted into the tubular outer wire 224, one end of which is fixed to the wire connecting portion 221, the other end is connected to a controlled member (not shown), and the wire connecting portion 221 moves linearly. It is configured to be able to move linearly in parallel.

  Here, the controlled member (not shown) to which the operating device 100 is connected operates according to the moving distance of the inner wire 222 by the predetermined distance k1. Specifically, the controlled member (not shown) is operated by operating a lever mechanism on the controlled member side connected to the other end of the inner wire 222 in response to the inner wire 222 moving a predetermined distance. A fin (not shown) that switches the air passage in the controlled member is switched, and an internal air circulation function that takes in and circulates the air in the vehicle and an external air introduction function that introduces and circulates the external air are mutually switched.

The first pulley member 23 includes a first fulcrum part 231, a second fulcrum part 232, and a third fulcrum part 233 around which the belt member 24 is wound.
The first fulcrum part 231 and the second fulcrum part 232 are arranged in a direction parallel to the front surface of the body 1 (left-right direction shown in FIG. 3), and the distance between them is a predetermined distance k1 (a controlled member (not shown)). It is arranged with a dimension larger than the movement distance of the inner wire 222 necessary for operation.

  The first fulcrum portion 231 is fixed at a predetermined position of the body 1 around an axis C1 extending in a direction orthogonal to the front surface (front and back directions shown in FIG. 1) in the vicinity of the lower left corner of the body 1.

4 is a cross-sectional view of the operation device 100 according to the embodiment shown in FIG.
The first fulcrum part 231 has a display part 25 on the front side end face.
The display unit 25 is formed of a light-transmitting material, is an operation position of the first operation knob 21, and displays the function of the controlled member. Specifically, for example, in the example illustrated in FIG. 2, the display unit 25 is provided with a display indicating an outside air introduction function and a display indicating an inside air circulation function.

The first fulcrum part 231 is formed in a cylindrical shape having a hollow part 231a, and the belt member 24 is wound around the outer peripheral surface 231b.
In the hollow portion 231a, a substrate 70 of the control unit 7 to be described later fixed to the body 1 is disposed, and the lighting device 6 that illuminates the display unit 25 from the back side is provided on the substrate 70.

Returning to FIG. 3, the second fulcrum part 232 is fixed at a predetermined position of the body 1 around the axis C <b> 2 extending in the direction orthogonal to the front surface in the vicinity of the lower right corner of the body 1.
The second fulcrum part 232 has the display part 25 on the front side end face, is formed in a cylindrical shape having a hollow part, the belt member 24 is wound around the outer peripheral surface, and the display part 25 is illuminated from the back side. The point where the device 6 is provided has the same configuration as that of the first fulcrum portion 231, and thus detailed description thereof is omitted.

  The third fulcrum part 233 is formed in a rod shape and is located at a predetermined distance k2 above the first fulcrum part 231 and the second fulcrum part 232, and is intermediate between the first fulcrum part 231 and the second fulcrum part 232. It is arranged at the position. That is, the first fulcrum part 231, the second fulcrum part 232, and the third fulcrum part 233 are arranged at the vertices of the triangle in plan view.

The first belt type operation mechanism 2 adjusts a predetermined distance k2 from the first fulcrum part 231 and the second fulcrum part 232 to the third fulcrum part 233, whereby the control member 22 with respect to the linear movement direction of the first operation knob 21 is adjusted. The angle r1 in the linear movement direction can be adjusted.
The predetermined distance k2 is set to a dimension that is larger than the outer diameter of the dial type operation mechanism 5 and forms an angle r1 that can connect the control member 22 to a controlled member (not shown).

The belt member 24 is formed in a belt-shaped annular body, and is wound around the first fulcrum part 231, the second fulcrum part 232, and the third fulcrum part 233 of the first pulley member 23.
The belt member 24 is provided with the first operation knob 21 between the first fulcrum part 231 and the second fulcrum part 232, and the wire connection part 221 of the control member 22 between the first fulcrum part 231 and the third fulcrum part 233. It is attached.

  That is, the first pulley member 23 has a linear movement direction (the first fulcrum part 231 and the first fulcrum part 231 and the second fulcrum part 232) with respect to the linear movement direction (the direction between the first fulcrum part 231 and the second fulcrum part 232) of the first operation knob 21. The third fulcrum part 233 is disposed so as to have an angle r1.

FIG. 5 is a view of the second belt type operating mechanism 3, the third belt type operating mechanism 4 and the dial type operating mechanism 5 of the operating device 100 according to the embodiment shown in FIG.
In FIG. 5, only the outer shape of the body 1 is indicated by a broken line.

  The second belt type operation mechanism 3 includes a second operation knob 31, a second pulley member 32, a belt member 33 with protrusions, a detected portion 34, a slide operation detection portion 35, and a rotation operation detection portion 36. It has.

  The second operation knob 31 has a proximal end fixed to the belt member 33 with a protrusion, protrudes leftward from a side operation opening 12 (see FIG. 1) formed on the left side surface of the body 1, and is gripped by an operator. The body 1 is configured to be linearly movable in a direction parallel to the side surface of the body 1 (vertical direction shown in FIG. 5).

  The second pulley member 32 includes a fourth fulcrum part 321 and a fifth fulcrum part 322 around which the belt member 33 with protrusions is wound.

The fourth fulcrum part 321 extends in the direction perpendicular to the front surface (front and back directions shown in FIG. 1) in the vicinity of the upper left corner of the body 1. The fourth fulcrum part 321 has a front side (front side shown in FIG. 1) end of the body 1 protruding from the front operation opening 13 (see FIG. 1), and a back side (back side shown in FIG. 1) end of the body 1. The part is attached to a predetermined position of the body 1 so as to be rotatable about the axis C1.
The fourth fulcrum part 321 includes a shaft part 321a formed in a cylindrical shape, and a rolling bearing 321b that is rotatably disposed on the outer periphery of the shaft part 321a and formed in a cylindrical shape.

The shaft part 321a has a display part 37 on the front side end face.
The display unit 37 is formed of a translucent material, is an operation position of the second operation knob 31 and the fourth fulcrum unit 321, and displays the function of the controlled member. Specifically, for example, in the example illustrated in FIG. 5, the display unit 37 is provided with a display indicating the switching of the air outlet and the ON / OFF function of the rear defroster.
Further, the display unit 37 is provided with a knob 38 that is held by an operator who rotates the fourth fulcrum unit 321.

  The rolling bearing 321b rotates together with the belt member 33 with the protrusion, and a scale portion 39 indicating a display of the function of the controlled member on the display portion 37 is provided at the front side end portion thereof.

The fifth fulcrum part 322 is fixed at a predetermined position of the body 1 around the axis C1 extending in the direction orthogonal to the front surface in the vicinity of the lower left corner of the body 1.
As shown in FIG. 4, the fifth fulcrum portion 322 is formed integrally with the first fulcrum portion 231 on the back side of the first fulcrum portion 231, and has a cylindrical shape having a hollow portion 322a integral with the hollow portion 231a. The belt member 33 with protrusions is wound around the outer peripheral surface 322b.

As described above, the first pulley member 23 and the second pulley member 32 are arranged on the shaft center where the second fulcrum part 232 (see FIG. 3) and the fourth fulcrum part 321 (see FIG. 5) are different from each other. The first fulcrum part 231 and the fifth fulcrum part 322 are arranged on the same axis C1.
In the present embodiment, the fifth fulcrum part 322 is provided integrally with the first fulcrum part 231. However, the first fulcrum part 231 and the fifth fulcrum part 322 are disposed on the same axis C1. If it is, you may comprise by the member different from the 1st fulcrum part 231.

  Moreover, you may provide a rolling bearing in the outer peripheral surface 231b and the outer peripheral surface 322b. By doing in this way, the drive of the belt member 24 and the belt member 33 with a protrusion becomes smooth. Further, the outer peripheral surface 231b and the outer peripheral surface 322b are not limited to rolling bearings, and may be provided with uneven gears so as to be rotatable. Unevenness may be formed. By doing in this way, operation of the 1st fulcrum part 231 and the 5th fulcrum part 322 can be made to follow smoothly operation of belt member 24 and belt member 33 with a projection.

The protrusion-equipped belt member 33 is formed in a belt-shaped annular body, and is wound around the fourth fulcrum part 321 (see FIG. 5) and the fifth fulcrum part 322 of the second pulley member 32.
The protrusion-equipped belt member 33 is provided with a protrusion 331 for detecting movement by the slide operation detection unit 35 in the vicinity of the side edge in the direction orthogonal to the circumferential direction (front and rear directions shown in FIG. 4). A plurality of members 33 are arranged at predetermined intervals along the moving direction of the member 33.

Returning to FIG. 5, the detected part 34 is provided on a line L <b> 1 connecting the axis of the fourth fulcrum part 321 and the axis C <b> 1 of the fifth fulcrum part 322, and rotates together with the fourth fulcrum part 321.
The detected portion 34 engages with the detected portion guide member 14 provided in the body 1 on the line L1, and is guided by the detected portion guide member 14 as the fourth fulcrum portion 321 rotates, so that the axis C1 Is engaged with the detected portion guide member 14 on a line L2 extending in the direction of the angle r2 with respect to the line L1. That is, the detected portion 34 engages with the detected portion guide member 14 on either the line L1 or the line L2.
Further, when the detected portion 34 is engaged with the detected portion guide member 14 on either the line L1 or the line L2 (for example, on the line L1 in the example shown in FIG. 5), the detected rotation operation is detected. When it is engaged with the detected portion guide member 14 on the other side (for example, on the line L2 in the example shown in FIG. 5), it is separated from the rotation operation detecting portion 36.

  The angle r2 is such that when the fourth fulcrum part 321 is rotated, the belt member 33 with protrusions wound around the fourth fulcrum part 321, the fourth fulcrum part 321, and the fifth fulcrum part 322 enters the body 1. It is set within a range where it does not come into contact with another incorporated member (for example, the dial type operation mechanism 5 in the example shown in FIG. 5).

  As described above, the second belt type operating mechanism 3 is operated by the operator from the state in which the detected portion 34 is engaged with the detected portion guide member 14 on the line L1 (the state indicated by the solid line in FIG. 5). The fourth fulcrum part 321 of the second pulley member 32 rotates about the axis C1 by an angle r2, and the detected part 34 is engaged with the detected part guide member 14 on the line L2 (in FIG. 5). A state indicated by a dotted line).

As shown in FIG. 4, the slide operation detection unit 35 is provided on a substrate 70 of the control unit 7 (described later) fixed to the body 1, and detects the movement of the protruding belt member 33.
The slide operation detection unit 35 is a detector switch that is turned ON / OFF by an operation unit that is swung by the protrusion 331 of the protrusion-equipped belt member 33. Thus, by using a two-contact circuit switch such as a detector switch, the operation direction can be detected, and the controlled part can be controlled in accordance with the operation direction.

Returning to FIG. 5, the rotation operation detection unit 36 detects the rotation of the fourth fulcrum part 321.
In the rotation operation detection unit 36, the detected portion 34 is engaged with the detected portion guide member 14 on either the line L1 or the line L2 (for example, on the line L1 in the example shown in FIG. 5). It is sometimes turned on, and on the other hand (for example, on the line L2 in the example shown in FIG. 5), it is turned off when engaged with the detected portion guide member 14.

The third belt type operation mechanism 4 is the same as the second belt type operation mechanism 3 except that the function of the controlled member to be controlled and the positions of the third operation knob 41 and the third pulley member 42 are different from those of the second belt type operation mechanism 3. The operation mechanism 3 is the same. Therefore, the same reference numerals are given to the portions that perform the same functions as those of the second belt type operation mechanism 3 described above, and overlapping descriptions are omitted as appropriate.
The third belt type operation mechanism 4 includes a third operation knob 41, a third pulley member 42, a belt member 33 with protrusions, a detected portion 34, a slide operation detection portion 35, and a rotation operation detection portion 36. It has.

  The third operation knob 41 is fixed to the protrusion-provided belt member 33 at the base end, protrudes to the right from the side operation opening 12 (see FIG. 1) formed on the right side surface of the body 1, and is held by the operator. The body 1 is configured to be linearly movable in a direction parallel to the side surface of the body 1 (vertical direction shown in FIG. 5).

  The third pulley member 42 includes a sixth fulcrum part 421 and a seventh fulcrum part 422 around which the protruding belt member 33 is wound.

The sixth fulcrum portion 421 extends in the direction orthogonal to the front surface (front and back directions shown in FIG. 1) in the vicinity of the upper right corner of the body 1. The sixth fulcrum part 421 has a front side (front side shown in FIG. 1) end of the body 1 protruding from the front operation opening 13 (see FIG. 1), and a rear side (back side shown in FIG. 1) end of the body 1 The part is attached to a predetermined position of the body 1 so as to be rotatable about the axis C2.
The sixth fulcrum part 421 includes a shaft part 421a formed in a cylindrical shape, and a rolling bearing 421b that is rotatably disposed on the outer periphery of the shaft part 421a and formed in a cylindrical shape.

The shaft part 421a has a display part 47 on the front side end face.
The display unit 47 is formed of a light-transmitting material, is an operation position of the third operation knob 41 and the sixth fulcrum unit 421, and displays the function of the controlled member. Specifically, for example, in the example shown in FIG. 5, the display unit 47 is provided with a display indicating the temperature adjustment and the ON / OFF function of the air conditioner.
Further, the display unit 47 is provided with a knob 48 that is gripped by an operator who rotates the sixth fulcrum part 421.

  The rolling bearing 421b rotates with the protrusion-provided belt member 33, and a scale portion 49 is provided at the front side end portion thereof to indicate the display of the function of the controlled member on the display portion 47.

The seventh fulcrum portion 422 is fixed at a predetermined position of the body 1 around the axis C2 extending in the direction orthogonal to the front surface in the vicinity of the lower right corner of the body 1.
The seventh fulcrum part 422 is the same as the fifth fulcrum part 322 of the second belt type operating mechanism 3 except that the seventh fulcrum part 422 is arranged on the same axis C2 as the second fulcrum part 232 instead of the first fulcrum part 231. Because of this configuration, the description is omitted.

The control unit 7 shown in FIG. 4 includes a substrate 70 fixed to the body 1, and a slide operation detection unit 35 and a rotation operation detection unit 36 are connected to the substrate 70. Although not shown, the control unit 7 includes a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), a device that communicates with a controlled unit, and the like.
The control unit 7 controls the controlled unit according to the number of times that the slide operation detection unit 35 has detected the protrusion 331 of the belt member 33 with protrusion. Further, the control unit 7 controls the controlled unit in accordance with ON / OFF of the rotation operation detection unit 36.

FIG. 6 is a functional block diagram of the control unit 7 according to the embodiment.
The control unit 7 includes a detection number counting unit 71, a rotation operation detection unit 72, and a controlled unit instruction unit 73, and is connected to, for example, an air conditioner 500 as a controlled unit.

The detection count unit 71 receives ON / OFF signals indicating ON / OFF from the slide operation detection unit 35 of the second belt type operation mechanism 3 and the slide operation detection unit 35 of the third belt type operation mechanism 4, respectively. Counts the number of ON / OFF signals received. Further, the operation direction of the second belt type operation mechanism 3 and the third belt type operation mechanism 4 is detected by ON / OFF input of the slide operation detection unit 35.
The rotation operation detection unit 72 receives ON / OFF signals indicating ON / OFF from the rotation operation detection unit 36 of the second belt type operation mechanism 3 and the rotation operation detection unit 36 of the third belt type operation mechanism 4, respectively. Receive.

  The controlled unit instruction unit 73 transmits to the air conditioner 500 a control signal based on the operation direction and the number of ON / OFF signals counted by the detection number counting unit 71 and the ON / OFF signal received by the rotation operation detection unit 72. .

Specifically, the controlled unit instruction unit 73, when the detection count unit 71 receives an ON / OFF signal from the slide operation detection unit 35 of the second belt type operation mechanism 3 with respect to a predetermined operation direction, A control signal is transmitted to the air conditioner 500 for instructing switching to the air blowing port set in advance for the number of ON / OFF signals for a predetermined operation direction.
In addition, the controlled unit instruction unit 73 performs a predetermined operation when the detection count unit 71 receives an ON / OFF signal from the slide operation detection unit 35 of the third belt type operation mechanism 4 with respect to a predetermined operation direction. A control signal instructing to adjust the temperature to a preset temperature based on the number of ON / OFF signals for the direction is transmitted to the air conditioner 500.

In addition, when the rotation operation detection unit 72 receives an ON / OFF signal from the rotation operation detection unit 36 of the second belt type operation mechanism 3, the controlled unit instruction unit 73 turns on / off the rear defroster. A control signal to be instructed is transmitted to the air conditioner 500.
In addition, when the rotation operation detection unit 72 receives an ON / OFF signal from the rotation operation detection unit 36 of the third belt type operation mechanism 4 with respect to a predetermined operation direction, the controlled unit instruction unit 73 performs a predetermined operation. A control signal for instructing ON / OFF of the air conditioner 500 in the operation direction is transmitted to the air conditioner 500. In this way, depending on the direction in which the slide operation detection unit 35 is switched according to the operation direction of each belt-type operation mechanism, the strength of the air flow rate, the temperature level, or the switching between outside air introduction or inside air circulation is determined. Regarding the switching of the outside air introduction or the inside air circulation, after the detection unit 50 is switched by an operation in one direction of the detected unit 41, the input may be canceled even if the detection unit 50 is switched in the same direction. .

Next, the operation of the operating device 100 according to the present embodiment will be described.
First, when the air conditioner 500 is turned on, the operator turns the sixth fulcrum part 421 to the ON side from the state where the sixth fulcrum part 421 of the third belt type operation mechanism 4 is arranged on the OFF side. Let Thereby, the control unit 7 transmits a control signal instructing to turn on the air conditioner 500 to the air conditioner 500.
Further, when turning on the rear defroster, the operator turns the fourth fulcrum part 321 to the ON side from the state where the fourth fulcrum part 321 of the second belt type operation mechanism 3 is arranged on the OFF side. . Thereby, the control unit 7 transmits a control signal instructing to turn on the rear defroster to the air conditioner 500.

When the operator switches the air blowing port, the second operation knob 31 is set so that the scale unit 39 is aligned with the display of the desired air blowing port on the display unit 37 of the fourth fulcrum part 321 of the second belt type operation mechanism 3. And the sliding belt member 33 is slid.
As a result, the belt member 33 with protrusions rotates around the fourth fulcrum part 321 and the fifth fulcrum part 322 as fulcrums. Then, the protrusions 331 of the protrusion-equipped belt member 33 turn on / off the slide operation detection unit 35 by the number of protrusions 331 arranged during the movement distance of the protrusion-provided belt member 33 by the operator's slide operation. In the control unit 7, the detection number counting unit 71 receives the on / off signal from the slide operation detection unit 35, counts the number of received on / off signals, and the controlled unit instruction unit 73 outputs the counted on / off signal. A control signal instructing switching to the air outlet set in advance for the number of times is transmitted to the air conditioner 500.

Further, when adjusting the temperature, the operator holds the third operation knob 41 so that the scale portion 49 is aligned with the display of the desired temperature on the display portion 47 of the sixth fulcrum portion 421 of the third belt type operation mechanism 4. Then, the protruding belt member 33 is slid.
Thereby, the belt member 33 with protrusions rotates and moves with the sixth fulcrum part 421 and the seventh fulcrum part 422 as fulcrums. Then, the protrusions 331 of the protrusion-equipped belt member 33 turn on / off the slide operation detection unit 35 by the number of protrusions 331 arranged during the movement distance of the protrusion-provided belt member 33 by the operator's slide operation. In the control unit 7, the detection number counting unit 71 receives the on / off signal from the slide operation detection unit 35, counts the number of received on / off signals, and the controlled unit instruction unit 73 outputs the counted on / off signal. A control signal instructing to adjust the temperature to a preset temperature is transmitted to the air conditioner 500.

When the operator switches from the inside air circulation function to the outside air introduction function, the operator grasps the first operation knob 21 of the first belt type operation mechanism 2, and displays the inside air circulation on the display unit 25 from the outside air. Move in a straight line to the direction showing the introduction.
As a result, the belt member 24 rotates around the first fulcrum part 231, the second fulcrum part 232, and the third fulcrum part 233. The wire connecting portion 221 of the control member 22 follows the belt member 24 and linearly moves in a direction inclined by an angle r1 with respect to a direction parallel to the bottom surface of the body 1. Then, the inner wire 222 of the control member 22 follows the linear movement of the wire connecting portion 221 and switches the operation of the controlled member (not shown) from the inside air circulation function to the outside air introduction function.

As described above, according to the present embodiment, the belt member 24 or the protrusion-provided belt member 33 incorporated in the body 1 and driven by the operation of the operator at the bottom operation opening 11 and the side operation opening 12. And at least two fulcrum parts (the first fulcrum part 231, the second fulcrum part 232, the third fulcrum part 233, the fourth fulcrum part 321 and the fifth fulcrum) around which the belt member 24 or the belt member 33 with protrusions is wound. Part 322, and a pulley member (first pulley member 23, second pulley member 32, and third pulley member 42) including a sixth fulcrum part 421 and a seventh fulcrum part 422), and belt member 24 or A plurality of belt-type operating mechanisms (first belt-type operating mechanism 2, second belt-type operating mechanism 3, and third belt-type operating mechanism 4) that control the controlled member by driving the belt member 33 with protrusions. With.
As a result, a plurality of functions of the controlled member can be controlled, and the operation of the operator is transmitted to the controlled member by driving the belt member 24 or the belt member 33 with protrusions, so that the operation of the operator is transmitted to the controlled member. The thickness of the mechanism can be reduced, and the depth of the operating device 100 can be shortened.

  Also, two or three fulcrum parts (first fulcrum part 231, second fulcrum part 232 and third fulcrum part 233, fourth fulcrum part 321 and fifth fulcrum part 322, sixth fulcrum part 421 and seventh Since another member can be disposed in a space surrounded by the fulcrum part 422) and the belt member 24 or the belt member 33 with protrusions, the space in the operating device 100 can be effectively utilized. Therefore, simplification of the structure and space saving can be achieved.

Further, in the first belt type operation mechanism 2 and the second belt type operation mechanism 3, the second fulcrum part 232 and the fourth fulcrum part 321 are arranged on different axes so that the first fulcrum part 231 and the fifth fulcrum part are provided. 322 was placed on the same axis. Further, in the first belt type operation mechanism 2 and the third belt type operation mechanism 4, the first fulcrum part 231 and the sixth fulcrum part 421 are arranged on different axes, and the second fulcrum part 232 and the seventh fulcrum part are provided. 422 was placed on the same axis.
Thereby, in the two belt type operation mechanisms, the width dimension of the operation device 100 can be shortened as compared with the case where the fulcrum portions are arranged at different positions. Therefore, simplification of the structure and space saving can be achieved.

In the second belt type operation mechanism 3, the fourth fulcrum part 321 rotates around the axis C <b> 1 of the fifth fulcrum part 322 by the operation of the operator. Then, the rotation operation detection unit 36 detects the rotation of the fourth fulcrum part 321. In the third belt type operation mechanism 4, the sixth fulcrum part 421 rotates around the axis C <b> 2 of the seventh fulcrum part 422 by the operation of the operator. Then, the rotation operation detection unit 36 detects the rotation of the sixth fulcrum part 421.
Thereby, for example, in the second belt type operation mechanism 3, in addition to the control of the controlled member by the operation of driving the belt member 33 with protrusions, the controlled member is controlled by the operation of rotating the fourth fulcrum portion 321. Can do. That is, two functions of the controlled member can be controlled by one belt type operation mechanism. Therefore, simplification of the structure and space saving can be achieved.

The first pulley member 23, the second pulley member 32, and the third pulley member 42 are a display unit 25, a display unit 37, and a display unit that display the function of the controlled member on the front surface facing the operator in use. 47.
Accordingly, the first pulley member 23, the second pulley member 32, and the third pulley member 42 not only function as a shaft of the belt member but also function as a display unit, so that space can be saved. . Therefore, simplification of the structure and space saving can be achieved.

The first pulley member 23 is disposed so as to have an angle r1 in the linear movement direction of the control member 22 with respect to the direction in which the belt member 24 is driven by the operation of the operator in the bottom surface operation opening 11. Yes.
Thus, the control member 22 can be moved in the linear movement direction of the predetermined angle r1 with respect to this direction, not limited to the direction in which the belt member 24 is driven by the operation of the operator. That is, the controlled member can be arranged at an arbitrary position, and the linear movement direction of the control member 22 can be matched with the direction in which the controlled member is operated, so that the degree of freedom in the layout inside the operating device 100 is improved. Therefore, the degree of freedom in layout can be improved while simplifying the structure and saving space.

(Deformation)
(1) In the present embodiment, the belt member 24 may be formed of a wire or a chain as long as the first operation knob 21 and the wire connecting portion 221 can be fixed. Further, the protrusion-equipped belt member 33 may be formed of a wire or a chain as long as the second operation knob 31 and the third operation knob 41 can be fixed and the slide operation detection unit 35 can be turned on and off.
The belt member 24 or the belt member 33 with protrusions is formed of a rubber material. However, the present invention is not limited to this. For example, a plurality of resin plates are arranged, and adjacent plates are connected to form a belt shape. A thing may be used.

(2) In the present embodiment, the first operation knob 21, the second operation knob 31, or the third operation knob 41 is fixed to the belt member 24 or the belt member 33 with protrusions. The operation knob 21, the second operation knob 31, and the third operation knob 41 are not provided, and the belt member 24 or the belt member 33 with protrusions can be directly slid at the bottom surface operation opening 11 and the side surface operation opening 12. May be. In this case, in order to prevent the belt member 24 or the protrusion-equipped belt member 33 from sinking due to the operator's slide operation, the belt member 24 or the protrusion-provided belt member 33 is formed in the bottom operation opening 11 and the side operation opening 12. It is desirable to provide a wall portion that is in sliding contact with the back surface of the surface to be operated.

(3) In this embodiment, the bottom surface operation opening 11 and the side surface operation opening 12 for the operator to slide the belt member 24 or the belt member 33 with protrusions are provided on the side surface of the body. Not limited. Depending on the internal layout of the operating device, the axis of the fulcrum portion of the belt member may be arranged in a direction parallel to the front surface of the body, and an opening for the operator to operate the belt member may be provided on the front surface of the body. Good.

(4) In the present embodiment, the controller device 100 includes functional configurations of a detection frequency counting unit 71, a rotation operation detection unit 72, and a controlled unit instruction unit 73 in the control unit 7. However, the functional configuration is not limited to this, and another control device connected to the controller device 100 may be provided. In this case, the operation device 100 transmits the ON / OFF signal detected by the slide operation detection unit 35 and the rotation operation detection unit 36 to the other control device. Another control device transmits a control signal based on the ON / OFF signal received from the operation device 100 to the air conditioning equipment as the controlled portion.

(5) In the present embodiment, the operation device 100 has been described with an example in which the air conditioner 500 is operated. However, the operating device of the present invention may be applied to the operation of other devices as long as it is an operating device that controls the controlled device with a wire or a control signal.

(6) Although the belt member 24 has been described as having an endless shape, the end member may have a configuration in which an extended portion corresponding to the operation stroke is wound around a fulcrum portion.

  Each embodiment and modification may be used in appropriate combination, but detailed description is omitted. Further, the present invention is not limited by the embodiments described above.

DESCRIPTION OF SYMBOLS 1 Body 2 1st belt type operation mechanism 3 2nd belt type operation mechanism 4 3rd belt type operation mechanism 5 Dial type operation mechanism 6 Illuminating device 7 Control part 10 Body 11 Bottom surface operation opening part 12 Side surface operation opening part 13 Front surface operation opening Part 14 Detected part guide member 21 First operation knob 22 Control member 23 First pulley member 24 Belt member 25, 37, 47 Display part 31 Second operation knob 32 Second pulley member 33 Protruding belt member 34 Detected part 35 Slide operation detection part 36 Rotation operation detection part 38, 48 Knob part 39, 49 Scale part 41 Third operation knob 42 Third pulley member 51 Operation knob 70 Substrate 71 Detection frequency counting part 72 Rotation operation detection part 73 Controlled Part instruction unit 100 Operating device 221 Wire connection unit 222 Inner wire 223 Control wire 22 Outer wire 225 Support portion 231 First fulcrum portion 231a Hollow portion 231b Outer peripheral surface 232 Second fulcrum portion 233 Third fulcrum portion 321 Fourth fulcrum portion 321a Shaft portion 321b Bearing 322 Fifth fulcrum portion 322a Hollow portion 322b Outer peripheral surface 331 Projection 421 Six fulcrum parts 421a Shaft part 421b Rolling bearing 422 Seventh fulcrum part 500 Air conditioning equipment C1, C2 Shaft core L1, L2 Line k1, k2 Predetermined distance r1, r2 Angle

Claims (5)

A body formed with an operation opening;
A belt member incorporated in the body and driven by an operator's operation in the operation opening; and a pulley member around which the belt member is wound and including at least two fulcrum portions, and the belt member A plurality of belt-type operation mechanisms that control the controlled member by driving;
An operating device comprising: The operating device according to claim 1,
Among the plurality of belt-type operation mechanisms, one of the belt-type operation mechanisms and the other belt-type operation mechanism have one fulcrum portion disposed on a different axis and the other fulcrum portion on the same axis. Being placed on the core,
An operation device characterized by. The operating device according to claim 1 or 2,
Among the plurality of belt-type operation mechanisms, at least one of the belt-type operation mechanisms is configured such that one of the fulcrum portions rotates around the axis of the other fulcrum portion by an operator's operation,
Further comprising a detection unit for detecting rotation of the fulcrum unit;
An operation device characterized by. In the operating device according to any one of claims 1 to 3,
The pulley member has a display unit for displaying a function of the controlled member on a front surface facing the operator in a use state;
An operation device characterized by. The operating device according to any one of claims 1 to 4,
The belt-type operation mechanism further includes a control member connected to the controlled member and attached to the belt member;
The pulley member is disposed so as to have an angle in a linear movement direction of the control member with respect to a direction in which the belt member is driven by an operation of an operator in the operation opening;
An operation device characterized by.

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