KR20220047237A - Rotation sensing device and rotation sensing method thereof and appliance therewith - Google Patents

Abstract

Disclosed are a rotation sensing device, a rotation sensing method and a home appliance including the rotation sensing device. The present disclosure includes: a first sensing target installed on a control shaft rotated in interoperation with the rotation of a handle, and making a position change in interoperation with the rotation of the control shaft; and a first rotation sensing part sensing the position change of the first sensing target in a contactless manner not coming into contact with the first sensing target. The first rotation sensing part includes a plurality of sensors placed a predetermined distance apart from each other, along a rotation path of the first sensing target, and sensing the first sensing target to generate a signal when brought into an ON state, and each of the sensors on different positions can generate different types of signals. Therefore, the present invention is capable of providing a sensing result with high reliability.

Description

A rotation detection device, and a rotation detection method and a home appliance having the rotation detection device TECHNICAL FIELD

The present invention relates to a rotation detection device, a rotation detection method, and a home appliance having the rotation detection device, and more particularly, to a rotation detection device for detecting the amount of rotation of a knob used for operating a household appliance; , to a home appliance including the rotation detection method and rotation detection device.

A cooking appliance is one of home appliances for cooking food, which is installed in a kitchen space and cooks food according to a user's intention. These cooking appliances may be classified in various ways according to the type of heat source or type used, and fuel.

When cooking appliances are classified according to a type of cooking, they can be classified into an open type and a closed type according to the shape of a space in which food is placed. Sealed cooking appliances include ovens and microwaves, and open cooking appliances include cooktops, hops, and the like.

The sealed cooking appliance is a cooking appliance that shields a space in which food is located and heats the shielded space to cook food. In addition, an open cooking appliance is a cooking appliance in which food or a container for storing food is located in an open space, and the food or food container is heated to cook food.

In the sealed cooking appliance, a cooking chamber is provided, which is a space that is shielded when food is placed and food is cooked. Such a cooking chamber becomes a space in which food is substantially cooked. A heat source is provided in the space inside or outside the cooking compartment to heat the cooking compartment.

In recent years, a combined cooking apparatus capable of cooking various foods and simultaneously cooking a plurality of foods while a closed type cooking device and an open type cooking device are installed at the same time to combine a plurality of heat sources has been proposed.

In the combined cooking appliance, an open cooking appliance is positioned above the closed cooking appliance. In addition, a plurality of heaters or burners are installed in the open cooking appliance to enable a plurality of dishes at the same time.

When the user is cooking in an oven such as barbecue or baking, or when roasting meat or fish, he cooks using a closed cooking device. Cooking is done using the device.

One of the most commonly used open cooking appliances is a gas stove type open cooking appliance, which cooks food using a flame generated when gas is burned.

There are various methods for a user to adjust the intensity of the flame of such a cooking appliance, and a method of controlling the heat power by adjusting the amount of rotation of the knob using a knob rotating around a predetermined rotation axis has been widely used traditionally. This knob is connected to a valve that controls the flow of gas to mechanically control the amount of opening and closing of the valve. This method is also applied.

In the case of a method of electronically controlling the opening/closing amount of the valve, a structure for accurately measuring the rotation amount of the knob is required. Also, in recent years, even when mechanically controlling the opening and closing amount of the valve, there are increasing cases of having a configuration for displaying the heating power of the cooking appliance in the form of text or lighting to the user. structure is required.

An object of the present invention is to provide a rotation detecting device capable of accurately measuring the amount of rotation of a knob, and a home appliance including the rotation detecting method and the rotation detecting device.

Another object of the present invention is to provide a rotation detection device capable of providing a reliable detection result while reducing the risk of fire due to gas leakage, a rotation detection method and a home appliance including the rotation detection device.

A rotation sensing device according to an aspect of the present invention includes: a first sensing object installed on an adjustment shaft that is rotated in association with the rotation of a handle, and whose position is changed in association with the rotation of the adjustment shaft; and a first rotation detection unit configured to sense a change in the position of the first detection object in a non-contact manner not in contact with the first detection object, wherein the first rotation detection unit detects a rotation path of the first detection object Accordingly, the sensor includes a plurality of sensors that are spaced apart from each other by a predetermined distance and generate a signal when the first sensing object is in an ON state, and each sensor having a different position generates a different kind of signal.

In addition, it is preferable that the first sensing object includes a magnetic member that generates a magnetic force, and the sensor includes a Hall sensor that detects the magnetic force of the magnetic member that is close within a predetermined distance.

In addition, the present invention further includes a rotating plate in the form of a disk installed on the adjustment shaft and rotated with the adjustment shaft about the adjustment shaft, wherein the sensor is preferably installed on one side of the rotation plate facing the sensor. Do.

In addition, it is preferable that the present invention further comprises a control unit for receiving the signal generated by the sensor, and generating an operation control signal set in response to the type of the received signal.

In addition, when two or more types of signals are simultaneously received by the control unit, it is preferable that the control unit selects any one of the received signals and generates an operation control signal set according to the type of the selected signal.

In addition, when two or more types of signals are simultaneously received or no signals are received by the control unit after the rotation of the adjustment shaft is made, the control unit selects a signal received immediately before that, and controls an operation set in response to the selected signal type It is desirable to generate a signal.

In addition, it is preferable that the present invention further comprises an auxiliary sensing unit for detecting whether the adjustment shaft is rotated to a position deviated from the initial position.

In addition, it is preferable that the auxiliary sensing unit includes a mechanical switch that is turned on or off while the connection state between the contacts is changed by the rotational force transmitted through the adjustment shaft.

In addition, the present invention further comprises a control unit for receiving the signal generated by the sensor, and generating an operation control signal set in response to the type of the received signal, the control unit, at least one of the plurality of sensors is turned on ( ON) state and when the auxiliary sensing unit is in an ON state, it is preferable to generate a set operation control signal in response to a received signal or a selected one of the received signals.

In addition, the present invention further comprises a control unit for receiving the signal generated by the sensor, and generating an operation control signal set in response to the type of the received signal, the control unit, at least one of the plurality of sensors is turned on ( ON) state and when the auxiliary sensing unit is in an OFF state, it is preferable to generate an operation control signal set in relation to the state of the sensor.

In addition, the present invention further includes a control unit for receiving a signal generated from the sensor, and generating an operation control signal set in response to the type of the received signal, wherein the control unit, any of the plurality of sensors is ON (ON) If the auxiliary sensing unit is not in an ON state, it is preferable to generate an operation control signal set in relation to the state of the auxiliary sensing unit.

In addition, a home appliance according to another aspect of the present invention includes: a first sensing object installed on an adjustment shaft rotated in association with the rotation of the handle, and whose position is changed in association with the rotation of the adjustment shaft; and a first rotation detection unit configured to sense a change in the position of the first detection object in a non-contact manner not in contact with the first detection object, wherein the first rotation detection unit detects a rotation path of the first detection object It includes a plurality of sensors that are spaced apart from each other by a predetermined distance according to each other and generate a signal when the first sensing object is in an ON state, and each sensor having a different position generates a different kind of signal. Includes sensing device.

A rotation detection method according to another aspect of the present invention includes: a signal receiving step of receiving a signal generated by the hall sensor; A signal grasping step of recognizing the type of the received signal; and a control signal generating step of generating an operation control signal corresponding to the identified signal type.

In addition, the present invention further includes a signal selection step of selecting any one of the received signals when two or more types of signals are simultaneously received, wherein the control signal generating step is set corresponding to the type of signal selected in the signal selection step. It is desirable to generate an operation control signal.

In addition, in the signal selection step, when two or more types of signals are simultaneously received, a previously received signal is selected among the two received signals, and if no signal is received after the rotation of the adjustment shaft is made, a signal received immediately before is selected It is preferable to do

In addition, the present invention further includes the step of receiving a signal generated from an auxiliary sensing unit that is turned on or off as the connection state between the contacts is changed by the rotational force transmitted through the control shaft, and the control signal is generated In the step, when at least one of the plurality of sensors is in an ON state and the auxiliary sensing unit is in an ON state, operation control set in response to a received signal or a signal selected from among the received signals It is desirable to generate a signal.

In addition, the present invention further includes the step of receiving a signal generated from an auxiliary sensing unit that is turned on or off as the connection state between the contacts is changed by the rotational force transmitted through the control shaft, and the control signal is generated In the step, when at least one of the plurality of sensors is in an ON state and the auxiliary sensing unit is in an OFF state, it is preferable to generate an operation control signal set in relation to the state of the sensor.

In addition, the present invention further includes the step of receiving a signal generated from an auxiliary sensing unit that is turned on or off as the connection state between the contacts is changed by the rotational force transmitted through the control shaft, and the control signal is generated In the step, when none of the plurality of sensors is in an ON state and the auxiliary sensing unit is in an ON state, it is preferable to generate an operation control signal set in relation to the state of the auxiliary sensing unit.

According to the rotation detection device of the present invention, the rotation detection method and the home appliance having the rotation detection device, it is possible to stably provide a high-accuracy knob rotation amount measurement result without interruption, and thereby output the rotation state of the knob handle It is possible to provide an effect of stably controlling the operation to be performed or the operation made through the rotation of the knob handle.

In addition, the present invention can contribute to significantly reducing the risk of fire due to gas leakage, and enables information on whether or not defective components for detecting the rotation of the knob handle to be quickly and accurately secured, and electronic components It is possible to provide the effect of providing a reliable detection result as it prevents malfunction due to noise or error.

In addition, the present invention provides an independent operation switch that is different in function and shape from the existing knob ring using a knob ring installed for finishing the knob handle, so that the user can easily select the operation switch suitable for the purpose, and thus improved ease of use can be provided, and by reducing the number of operation switches disposed on the front of the home appliance, it is possible to improve the aesthetics of the front of the appliance.

In addition, the present invention provides a function in which a physical power transmission operation through manipulation of a knob handle and a sensing operation for sensing manipulation of the knob handle are simultaneously performed, while suppressing the increase in parts and assembly process and manufacturing cost required for implementing this function. This can provide the effect of effectively improving the sensing performance for manipulation of a manipulation switch such as a knob handle and a knob ring, so that the manufacturing operation can be made more easily.

1 is a view showing a home appliance having a timer function.
2 is a front view showing the front of the knob assembly according to an embodiment of the present invention.
Figure 3 is a side view showing a coupling state of the knob assembly according to an embodiment of the present invention.
Figure 4 is an exploded perspective view showing an exploded state of the knob assembly according to an embodiment of the present invention.
Figure 5 is a cross-sectional view showing a cross-section of the coupling state of the knob assembly according to an embodiment of the present invention.
Figure 6 is an exploded perspective view showing an exploded state of the knob ring according to an embodiment of the present invention.
FIG. 7 is a rear perspective view illustrating a rear surface of some parts of the knob ring shown in FIG. 6 .
8 is a rear view showing the assembly structure of the knob assembly according to an embodiment of the present invention.
9 is a view showing an operation state in which the knob ring of the knob assembly shown in FIG. 8 is rotated counterclockwise.
10 is a view showing an operation state in which the knob ring of the knob assembly shown in FIG. 8 is rotated clockwise.
11 is an enlarged side view of a portion of a knob assembly according to an embodiment of the present invention.
12 is an exploded perspective view illustrating an exploded state of the knob assembly shown in FIG. 11 .
13 is a diagram schematically showing the configuration of a first sensing object and a first rotation sensing unit according to an embodiment of the present invention.
FIG. 14 is a view showing a first example of a change state of a position of a first sensing object shown in FIG. 13 .
15 is a diagram schematically showing the configuration of a second sensing object and a second rotation sensing unit according to an embodiment of the present invention.
FIG. 16 is a view showing an example of a position change state of the second sensing object shown in FIG. 15 .
17 is a configuration diagram schematically showing the configuration of a rotation sensing device according to an embodiment of the present invention.
18 is a flowchart illustrating a knob rotation detection process of a rotation detection device according to an embodiment of the present invention.
19 is a diagram illustrating a second example of a change state of a position of a first sensing object.
20 is a diagram illustrating a third example of a change state of a position of a first sensing object.
21 is a flowchart illustrating a signal selection process for generating an operation control signal of a rotation sensing device according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, an embodiment of a home appliance having a rotation sensing device, a rotation sensing method and the rotation sensing device according to the present invention will be described. For the convenience of description, the thickness of the lines shown in the drawings, the size of components, etc. may be exaggerated for clarity and convenience of description. In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

[General structure of home appliances having a timer function]

1 is a view showing a home appliance having a timer function.

Referring to FIG. 1 , a home appliance such as a cooking appliance having an oven includes a knob 11 for operating the operation of the appliance on the front side, a knob 12 for adjusting the timer time, and the state of the appliance. It may include a display 15 for displaying, and a switch 16 for separate operation.

Since a long operation time is often required for home appliances such as a cooking appliance having an oven, a timer for setting the operation time is often installed in these home appliances.

In addition, the knob 11 for controlling the heat power, rotation speed, intensity of operation, etc. and the knob 12 for adjusting the timer time may be provided in the form of separate switches having different shapes or operating methods, respectively, For unity of design and convenience of operation, it is common to provide a plurality of one type of rotary switch in the form of an arrangement.

In addition, the display 15 serves to display the operation state of the home appliance. When the home appliance is a cooking appliance, the information displayed on the display 15 may be an output (temperature) of a burner, a timer time, a cooking mode of an automatic cooking function, and the like.

However, as the number of craters having a timer function increases, the number of timer handles increases accordingly, and accordingly, the shape of the front surface of the home appliance becomes very complicated, which causes a problem in that the aesthetics of the front surface of the home appliance is deteriorated.

Also, in the home appliance, the knob 11 for operating the operation of the home appliance and the knob 12 for adjusting the timer time are provided in the form of the same type of switch, so which knob of the design performs what function It is difficult for the user to intuitively recognize it, and thus there is a problem in that the ease of use is deteriorated.

In order to solve the above problems, the present invention provides a knob assembly having an improved structure so as to not only provide improved usability, but also improve the aesthetics of the front of the device.

Hereinafter, each component of the knob assembly according to an embodiment of the present invention will be described. Here, a case in which the home appliance is a cooking appliance will be described as an example. However, the home appliance of the present invention is not limited thereto, and in addition to the cooking appliance, a knob for operating the operation of the household appliance, such as a heater for heating or a dishwasher, and a timer for adjusting the operation time of the household appliance are provided together. It may include all home appliances.

[Structure of the knob handle]

Figure 2 is a front view showing a front view of the knob assembly according to an embodiment of the present invention, Figure 3 is a side view showing a coupling state of the knob assembly according to an embodiment of the present invention. Also, Figure 4 is an exploded perspective view showing an exploded state of the knob assembly according to an embodiment of the present invention, Figure 5 is a cross-sectional view showing a cross-section of the coupled state of the knob assembly according to an embodiment of the present invention.

2 to 5 , the knob knob 110 is connected to the valve shaft 194a of the valve assembly 190 provided to adjust the thermal power.

In this embodiment, the knob knob 110 is illustrated as being configured as a non-return type rotary switch. The knob handle 110 is provided in a form that maintains the position rotated by the user, and the output of the corresponding cooker can be recognized according to the angle at which the knob handle 110 is rotated.

For example, in the case of a gas burner, the valve assembly 190 is a valve for controlling the gas supply amount, and in the case of an electric range or an induction range, an output control means (for example, variable resistor).

As noted above, the knob knob 110 is connected to the valve shaft 194a of the valve assembly 190 . In the knob assembly structure of a general cooking appliance, the knob handle 110 is directly coupled to the valve shaft. However, in the structure in which the knob handle 110 is directly coupled to the valve shaft 194a as described above, the distortion due to the tolerance of the valve shaft 194a is directly transmitted to the knob handle 110, and accordingly, the knob handle 110 There is a problem that the alignment of the and knob ring 120 is misaligned.

In consideration of this, in the knob assembly of this embodiment, the knob knob 110 is not directly coupled to the valve shaft 194a, but the knob shaft 194b is coupled to the knob knob 110, and the knob shaft 194b A structure is provided in which the connection of the valve shaft 194a and the universal joint 170 is made.

The universal joint 170 serves to absorb the position error of the valve shaft 194a between the knob shaft 194b and the valve shaft 194a, and controls the rotational operation and the pressing operation of the knob handle 110 to the valve shaft (194a) performs the operation of forwarding.

Hereinafter, a shaft connection body formed by connecting the valve shaft 194a of the valve assembly 190 and the knob shaft 194b coupled to the knob handle 110 will be referred to as an adjustment shaft 194 .

The knob handle 110 has a basically circular shape and is provided in a form including a protruding handle portion. In this embodiment, the handle portion is illustrated as being protruding in a bar shape, but the shape of the handle portion may be variously changed.

The knob handle 110 may be made of a synthetic resin injection material or may be manufactured by processing a metal material. The material and shape of the knob handle 110 may be variously modified.

[Structure of knob ring]

The knob ring 120 is disposed on the outer circumferential surface of the knob handle 110 , and is a component that improves the appearance of the knob handle 110 .

Basically, the knob ring 120 serves to support the knob handle 110 and to improve the appearance quality of the cooking appliance by finishing the exterior of the knob handle 110 .

In addition, the knob ring 120 of the present embodiment is provided to serve as a timer operation switch and as a display for displaying the timer time and the amount of heat.

That is, the knob ring 120 is rotatably installed independently of the knob handle 110 , and the timer time can be set through the rotation operation of the knob ring 120 installed in this way, while on the knob ring 120 . A display 123 is provided so that the timer time and the size of the thermal power can be displayed through the display 123 .

To this end, in the knob assembly of this embodiment, a first rotation detecting unit 300 for detecting the amount of rotation of the knob handle 110 , and a second rotation detecting unit 350 for detecting the amount of rotation of the knob ring 120 . ) is provided. The first rotation detection unit 300 detects the amount of rotation of the adjustment shaft 194 connected to the knob handle 110 . In addition, the second rotation detecting unit 350 detects the rotation of the support ring 150 connected to the knob ring 120 .

The knob handle 110 and the knob ring 120 are installed to be exposed to the outside of the front panel C of the cooking appliance, and the display 123 provided in the knob ring 120 installed in this way has heat power, timer time, etc. can be displayed.

The thermal power displayed on the display 123 may be a value calculated based on a value detected by the rotation amount of the knob handle 110 , and the timer time displayed on the display 123 is the rotation amount of the knob ring 120 . It may be a value calculated based on the detected value.

The display 123 may be configured in a form in which a portion for displaying heat power and a portion for displaying a timer time are separately provided, but in this embodiment, the heat power and timer time are selectively displayed on the display 123. is exemplified

For example, the operation of the display 123 may be performed in the form of basically displaying only heat power when a timer is not set, and displaying heat power for a certain period of time and then displaying the timer time for a certain time when a timer is set. .

At this time, by differentiating the lighting color when the thermal power is displayed and the lighting color when the timer time is displayed, it is more preferable to allow the user to easily check whether the displayed number indicates the thermal power or the timer time. Do.

For example, a red color may indicate thermal power, and a white (or blue) color may indicate a timer time. When both firepower and timer are displayed, after displaying the firepower for 2 seconds, the timer can be displayed for the next 2 seconds.

As described above, by allowing both the heating power and the timer time to be displayed through the knob assembly, it is possible to effectively provide the user with information necessary for using the cooking appliance without the need to install a separate display on the front panel C.

[Structure of the support ring]

The support ring 150 is coupled to the rear surface of the knob ring 120 and is provided to rotate integrally with the knob ring 120 . At this time, the amount of rotation of the support ring 150 and the amount of rotation of the knob ring 120 are the same, and therefore, by sensing the amount of rotation of the support ring 150 , the manipulation of the knob ring 120 can be detected.

To this end, the support ring 150 may be provided with a knob ring gear part G2.

According to this embodiment, the support ring 150 may include a coupling shaft portion 151 , a flange portion 152 , and a wing portion 153 .

The coupling shaft portion 151 is a portion rotatably supported by the support frame 140 through the support frame 140 . The coupling shaft portion 151 may be formed in a circular tube shape, and a space through which the adjustment shaft 194 can pass is formed in the coupling shaft portion 151 . In addition, the coupling shaft portion 151 may be coupled to the knob ring 120 through the front panel C and the support frame 140 , whereby the support ring 150 may be rotated integrally with the knob ring 120 . A bond is made that allows

The flange part 152 is formed in a flange shape protruding outward in the radial direction of the coupling shaft part 151 from the rear end of the coupling shaft part 151 . In the present embodiment, a direction toward the outside of the front panel (C) with respect to the front panel (C) is referred to as a front, and a direction toward the valve assembly 190 is referred to as a rear.

The flange portion 152 forms a plane in contact with the support frame 140 on the rear side of the support frame 140, thereby preventing the support ring 150 from departing forward, and the support ring 150 moves forward and backward. It plays a role so that it can be rotated stably without being shaken in the direction.

The wing part 153 is formed to protrude outward in the radial direction of the coupling shaft part 151 from the outer peripheral surface of the coupling shaft part 151 . Unlike the flange portion 152 formed in a disk shape surrounding the coupling shaft portion 151 , the wing portion 153 is formed in a rod shape extending outward in the radial direction of the coupling shaft portion 151 .

The wing portion 153 is inserted into the fixed frame 160 . The wing part 153 may move within the movable area inside the fixed frame 160 , and its movement is restricted from a point where it interferes with the upper inner wall or the lower inner wall of the fixed frame 160 .

As such, when the movement range of the wing portion 153 is limited by the fixed frame 160 , the bidirectional rotation angle of the support ring 150 can be limited within a predetermined range. In addition, the wing portion 153 is also a coupling portion between the elastic member (S1, S2) and the support ring 150 to be described later.

[Structure of support frame]

The support frame 140 is coupled to the front panel C and serves to support the knob ring 120 . The knob handle 110 and the knob ring 120 are coupled to an aligned position of the front panel (C), and the front panel (C) is made of a thin metal material. Therefore, when a hole is formed in the front panel C and the knob ring 120 directly rubs against the hole and rotates, a problem in which the knob ring 120 is cut due to the front panel C occurs.

In consideration of this point, in this embodiment, the support frame 140 is installed at the rear of the hole formed in the front panel C, and the knob ring 120 is supported in the support frame 140 installed in this way. By allowing the rotation of the knob 120 to be made, a structure for suppressing the occurrence of friction between the knob ring 120 and the front panel C during the rotation of the knob ring 120 is provided.

According to this embodiment, the support frame 140 may include a frame body portion 141 , a through hole 143 , and a support portion 145 .

The frame body 141 forms a skeleton of the support frame 140 and is coupled to the front panel C so as to be located on the rear side of the front panel C.

And a through hole 143 corresponding to the outer diameter of the support ring 150 coupled to the knob ring 120 is formed inside the frame body 141 to pass through. The through hole 143 forms a passage for the coupling shaft portion 151 of the support ring 150 to pass through the support frame 140 in the front-rear direction.

A support portion 145 is formed on the outside of the passage hole 143 to form a side wall for rotatably supporting the coupling shaft portion 151 around the passage hole 143 . The support ring 150 is seated on the support part 145 provided in this way, and accordingly, the support ring 150 is supported by the support frame 140 so that it can be rotated at a predetermined position.

And the knob ring 120 coupled to the support ring 150 can be rotated about a certain axis on the support frame 140 through the support structure between the support frame 140 and the support ring 150 made as described above. is strongly supported

In other words, the position of the knob ring 120 is determined by the support frame 140 , and since the support frame 140 is fastened to the front panel C, the position of the knob ring 120 is determined by the front panel C. can be fixed based on

As described above, the support frame 140 surrounds the outer circumferential surface of the support ring 150 , and serves to support the support ring 150 so that it can rotate about a certain axis.

In addition, the support frame 140 is coupled to the guide rod 210 provided in the burner frame 200 to which the valve assembly 190 is fixed.

The guide rod 210 is provided for fixing between the burner frame 200 and the support frame 140 , and the support frame 140 coupled to the guide rod 210 is positioned at a predetermined position with respect to the burner frame 200 . can be fixed.

[Structure of fixed frame]

The fixing frame 160 is provided to prevent the support ring 150 from leaving the fixing frame 160 to the rear (to the inner side of the home appliance), and is provided on the rear side of the front panel (C). It is installed in the support frame 140 and is fastened to the support frame 140 by means of a fastening means such as a screw.

In addition, the fixed frame 160 also serves to restrict the rotation range of the support ring 150 . The fixed frame 160 limits the support ring 150 and the knob ring 120 to rotate in the left and right directions only within a predetermined angle range.

The fixed frame 160 is formed in a shape similar to a bow tie, and the portion corresponding to the wings of the butterfly is a portion that limits the support ring 150 to rotate within a certain angular range, and the wings of both sides The connecting portion becomes a portion that prevents the rearward separation of the support ring 150 .

According to this embodiment, the fixing frame 160 may include a fixing part 161 and a wing inserting part 163 .

The fixing part 161 is coupled to the support frame 140 to support the support ring 150 . This fixing portion 161 corresponds to a portion connecting the wings of both sides on the fixing frame 160 formed in a shape similar to a bow tie.

Specifically, the fixing part 161 is disposed on the rear side of the flange part 152 of the support ring 150, and is coupled to the frame body part 141 with the flange part 152 therebetween and the flange part 152. And the wing portion 153 supports the support ring 150 in a direction in close contact with the frame body portion (141).

Accordingly, the support ring 150 is positioned in the front-rear direction in a form in which the front side of the flange part 152 is supported by the support frame 140 and the rear side of the flange part 152 is supported by the fixed frame 160 . is arrested The support ring 150 may be rotated at a predetermined position in a state in which the forward and backward positions are constrained in this way, thereby stably fixing the rotational position of the knob ring 120 .

The blade inserts 163 are respectively disposed on both sides of the lateral direction of the fixing portion 161 . The wing insert 163 corresponds to a portion corresponding to the wings of a butterfly on the fixed frame 160 formed in a shape similar to a bow tie.

The wing insert 163, the wing 153 of the support ring 150 is inserted so that it can be rotated within a predetermined angle range. That is, the wing part 153 inserted into the wing insert 163 is movable within the movable region inside the wing insert 163 , and the upper inner wall or the lower inner wall of the wing insert 163 interferes with the point. From there, its movement is restricted.

When the movement range of the wing portion 153 is limited by the wing insertion portion 163 as described above, the bidirectional rotation angle of the support ring 150 may be limited within a predetermined range.

[Structure of the bearing shell]

The bearing shell 130 is a configuration that performs the role of a bearing so that the operation of the knob ring 120 can be performed smoothly.

The bearing shell 130 may include a cylindrical portion 134 having a cylindrical shape, and a disk portion 132 bent from the cylindrical portion 134 and protruding in the radial direction.

The cylindrical portion 134 is inserted between the outer circumferential surface of the support ring 150 coupled to the knob ring 120 and the inner circumferential surface of the fixing frame 160 . The cylindrical portion 134 serves to reduce friction between the support ring 150 and the fixed frame 160 .

The disc part 132 is inserted between the front panel C and the knob ring 120 . The disk portion 132 serves to reduce friction between the knob ring 120 and the front panel (C). In addition, the disc part 132 separates the knob ring 120 from the front panel C by a predetermined interval, so that when the knob ring 120 is operated, the knob ring 120 comes into contact with the front panel C and the front panel C ) may play a role in suppressing the occurrence of scratches.

[Structure of elastic member]

According to the present embodiment, the knob ring 120 is provided in a form in which a return type operation is possible. For example, the knob ring 120 is rotatably operated within a predetermined angular range in a clockwise or counterclockwise direction, and is provided in a form that can return to its original position when the external force is released.

The elastic members S1 and S2 provide a restoring force for returning the knob ring 120 to the initial position. The elastic members S1 and S2 may include a first elastic member S1 providing a restoring force in a clockwise direction and a second elastic member S2 providing a restoring force in a counterclockwise direction.

In this embodiment, each of the elastic members (S1, S2) is exemplified as being provided in the form of a coil spring in which one side in the longitudinal direction is fixed to the support ring 150 and the other side in the longitudinal direction is fixed to the support frame 140 .

According to this, the wing portion 153 of the support ring 150 is provided with a wing side coupling portion 155 to which one side of the elastic members S1 and S2 in the longitudinal direction is coupled, and the frame body portion of the support frame 140 ( Frame-side coupling portions 147 and 148 to which the other side in the longitudinal direction of the elastic members S1 and S2 are coupled are provided in the 141 .

In this embodiment, the wing-side coupling portion 155 and the frame-side coupling portions 147 and 148 are illustrated as being provided in the form of projections protruding from the wing portion 153 or the frame body portion 141, respectively. And each elastic member (S1, S2) is fixed to the elastic member (S1, S2) in the form that the ring portion provided on both sides in the longitudinal direction is hooked on the wing side coupling part 155 and the frame side coupling part 147, 148, respectively. can be done

In addition, the frame side coupling parts 147 and 148 are disposed above the wing side coupling part 155 and the first frame side coupling part 147 to which the first elastic member S1 is coupled, and the wing side coupling part 155 . It may be formed by including a second frame-side coupling portion 148 that is disposed at the lower portion to which the second elastic member (S2) is coupled.

That is, the first elastic member (S1) is installed in such a way that one side in the longitudinal direction is coupled to the wing side coupling part 155 and the other side in the longitudinal direction is coupled to the first frame side coupling part 147 . And the second elastic member (S2), the longitudinal direction one side is coupled to the wing side coupling portion 155, the other longitudinal direction is installed in a form coupled to the second frame side coupling portion (148).

When no external force is applied, the elastic forces of the first and second elastic members S1 and S2 installed as described above are balanced, and accordingly, the knob ring 120 maintains its initial position.

Since the support ring 150 and the knob ring 120 rotate integrally, the knob ring 120 maintains its initial position by the elastic force of the elastic members S1 and S2 connected to the support ring 150 . And the knob ring 120 maintaining the initial position in this way can rotate at a certain angle in the clockwise or counterclockwise direction, and when the external force is released in the rotated state, by the restoring force provided by the elastic members S1 and S2 It can return to its original position again.

For example, when the knob ring 120 is operated counterclockwise, the first elastic member S1 extended by the rotation of the knob ring 120 returns the knob ring 120 to its original position, that is, to the initial position. The second elastic member S2 extended by the rotation of the knob ring 120 returns the knob ring 120 to the initial position when the knob ring 120 is operated in the clockwise direction. It can provide resilience for

[Detailed structure of knob ring]

6 is an exploded perspective view illustrating an exploded state of the knob ring according to an embodiment of the present invention, and FIG. 7 is a rear perspective view illustrating a rear surface of some parts of the knob ring shown in FIG. 6 .

6 and 7 , the knob ring 120 according to an embodiment of the present invention may include a knob ring body 124 , a rear plate 125 , and a support pipe 126 .

The knob ring body 124 forms the exterior of the knob ring 120 . In this embodiment, the knob ring body 124 is illustrated as being formed in a shape including a ring shape.

The rear plate 125 is formed in a shape including a disk shape and is coupled to the rear surface of the knob ring body 124 . The rear plate 125 includes a support plate 125b that enters the inside of the front panel C (refer to FIG. 3 ) and protrudes toward the inside of the cooking appliance. And, inside the support plate 125b, a support hole 125c for supporting the adjustment shaft 194 while forming a passage for the adjustment shaft 194 (see FIG. 3) to pass through the knob ring 120 is provided.

In addition, a support pipe 126 provided to support the adjustment shaft 194 is coupled to the rear plate 125 . The support pipe 126 includes a flange 126a coupled to the rear plate 125, a tapered pipe 126b extending from the flange 126a, and a support lip 126d extending longer than the tapered pipe 126b. ) can be included.

The tapered pipe (126b) has a tapered shape whose diameter becomes narrower as it goes away from the flange (126a), and a support part (126c) for supporting the adjustment shaft (194) is provided at an end thereof.

In the knob ring 120 having the configuration as described above, a two-point support structure in which the support hole 125c and the support part 126c support the adjustment shaft 194 is provided.

In the present embodiment, the adjustment shaft 194 is not constrained to a fixed position as in the prior art, but is movably installed by a universal joint, so a structure capable of stably supporting the adjustment shaft 194 is required.

To this end, in this embodiment, a two-point support structure in which the support hole 125c and the support part 126c of the adjustment shaft 194 is supported is provided by the knob ring 120, so that the support of the adjustment shaft 194 is can be done stably.

In addition, the knob ring 120 is a support structure that supports the adjustment shaft 194 at two or more points, as well as a support capable of supporting the front end of the gear unit G1 coupled to the adjustment shaft 194 (refer to FIG. 4 ). A structure can also be provided.

Meanwhile, in the present embodiment, the knob ring 120 is provided with a display 123 capable of displaying the heat power or the timer time. The display unit 123 is coupled to the knob ring body 124 through the display housing 122 , and the closing cap 121 is coupled to the outside thereof. The closing cap 121 is preferably formed of a transparent or translucent material so that information (numbers) displayed on the display 123 can be visually recognized from the outside.

8 is a rear view showing an assembly structure of a knob assembly according to an embodiment of the present invention, and FIG. 9 is a view showing an operation state in which the knob ring of the knob assembly shown in FIG. 8 is rotated counterclockwise; 10 is a view showing an operation state in which the knob ring of the knob assembly shown in FIG. 8 is rotated clockwise.

For convenience of illustration, illustration of the front panel is omitted in FIGS. 8 to 10 .

3 and 8 , the knob handle 110 and the knob ring 120 are coupled to the front side of the front panel, and the support frame 140, the support ring 150 and the fixing frame 160 are coupled to the rear side of the front panel. ) are combined.

The fixing frame 160 is fastened to the rear surface of the front panel C, and the support ring 150 passes through the front panel and is fastened to the knob ring 120 . At this time, the rotation center of the support ring 150 is arranged to coincide with the rotation center of the knob handle (110). The support ring 150 serves to constrain the rotation center of the knob handle 110 to be in the correct position with respect to the front panel (C). That is, when the support ring 150 is fixed at the correct position with respect to the front panel, the knob handle 110 can be fixed at the correct position with respect to the front panel C.

The support ring 150 is inserted into the support frame 140 , passes through the front panel and partially protrudes toward the front of the front panel. The front end of the support ring 150 is formed in a cylindrical shape, and the cylindrical portion protrudes toward the front of the front panel (C).

The knob ring 120 is coupled to the cylindrical portion of the support ring 150 protruding toward the front of the front panel (C). As the knob ring 120 is coupled to the support ring 150 supported by the support frame 140 , as a result, a support structure in which the knob ring 120 is supported by the support frame 140 is formed.

The manipulation of the knob ring 120 may be recognized by the rotation of the support ring 150 , which is rotated in association with the rotation of the knob ring 120 . Since the knob ring 120 is a portion exposed to the outside of the front panel C, the second rotation detecting unit 350 for detecting the manipulation of the knob ring 120 is located around the knob ring 120 from the outside of the front panel. It is not good in appearance to be installed.

In consideration of this point, in this embodiment, the second rotation detection unit 350 is installed around the support ring 150 inside the front panel, and the second rotation detection unit 350 installed in this way is located inside the front panel. The rotation of the knob ring 120 may be detected in a manner that detects the rotation of the support ring 150 .

Meanwhile, in the knob assembly structure of the present embodiment, a fixing frame 160 is provided to prevent the support ring 150 from being separated to the rear surface so that the support ring 150 can stably operate.

The fixing frame 160 is provided in a form that crosses the rear surface of the support ring 150 and is fixed to the support frame 140 . This fixed frame 160, while preventing the support ring 150 from deviated to the rear surface, serves to limit the rotation range of the support ring 150 within a specified range.

According to the present embodiment, the support ring 150 has a wing portion 153 formed to extend laterally from the center of the support ring 150 , and the wing portion 153 is located inside the fixed frame 160 . is inserted

As such, the wing part 153 inserted into the fixed frame 160 is movable within the movable area inside the fixed frame 160 , and a point that interferes with the upper inner wall or lower inner wall of the fixed frame 160 . From there, its movement is restricted.

As such, when the movement range of the wing portion 153 is limited by the fixed frame 160 , the bidirectional rotation angle of the support ring 150 can be limited within a predetermined range.

In addition, by applying a structure such that the wing part 153 is provided on both sides of the support ring 150 and the movement range of each wing part 153 is made at the same position, the rotation range of the support ring 150 is limited This can also be made more stable.

In addition, the support ring 150 is connected to a pair of elastic members S1 and S2 that provide an elastic force for returning the support ring 150 rotated to a position spaced apart from the initial position to the initial position.

Since the support ring 150 and the knob ring 120 rotate integrally, the knob ring 120 maintains its initial position by the elastic force of the elastic members S1 and S2 connected to the support ring 150 . And the knob ring 120 maintaining the initial position in this way can rotate at a certain angle in the clockwise or counterclockwise direction, and when the external force is released in the rotated state, by the restoring force provided by the elastic members S1 and S2 You can return to the initial position again.

For example, the first elastic member (S1) of the pair of elastic members (S1, S2), as shown in FIG. 9, the support ring 150 by the operation of the knob ring 120 is counterclockwise When rotated to provide an elastic force acting in the clockwise direction so that the support ring 150 can be returned to the initial position. And the second elastic member (S2), which is the other one of the pair of elastic members (S1, S2), as shown in FIG. 10, the support ring 150 by the manipulation of the knob ring 120 clockwise When rotated, the support ring 150 provides an elastic force acting in a counterclockwise direction so that it can be returned to the initial position.

[Structure of the first sensing object and the first rotation sensing unit]

11 is a perspective view illustrating a portion of the knob assembly according to an embodiment of the present invention, and FIG. 12 is a perspective view illustrating the knob assembly shown in FIG. 11 from another direction. Also, FIG. 13 is a diagram schematically showing the configuration of a first sensing object and a first rotation sensing unit according to an embodiment of the present invention, and FIG. 14 is a view showing a change in position of the first sensing object shown in FIG. 13. .

11 and 12 , the knob assembly according to the present embodiment may further include a configuration for detecting a rotation operation of the knob handle 110 and a rotation operation of the knob ring 120 .

According to the present embodiment, the first sensing object M1 and the first rotation detecting unit 300 are provided as a configuration for detecting the rotation operation of the knob handle 110 , and the rotation operation of the knob ring 120 is detected. A second sensing object M2 (refer to FIG. 15 ) and a second rotation sensing unit 350 are provided for the following configuration.

First, looking at the configuration of the first sensing object M1 and the first rotation sensing unit 300 with reference to FIGS. 11 to 13 , the first sensing object M1 is positioned in association with the rotation of the adjustment shaft 194 . is provided to change, and the first rotation detection unit 300 detects the rotation of the adjustment shaft 194 by detecting a change in the position of the first detection object M1, and through this, the knob handle connected to the adjustment shaft 194 (110) sense the rotation.

The first sensing object M1 is a configuration to be detected by the first rotation sensing unit 300 and is installed on the adjustment shaft 194 . In this embodiment, it is exemplified that the rotating plate 250 is installed on the adjustment shaft 194 , and the first sensing object M1 is installed on the rotating plate 250 .

According to this, the rotating plate 250 is provided in the form of a disk in which the adjustment shaft 194 passes through the center, and is coupled to the outer peripheral surface of the adjustment shaft 194 to rotate the adjustment shaft 194 when the adjustment shaft 194 rotates. As a result, it can be rotated together with the adjustment shaft 194 .

And the first sensing object M1 is installed on the rotating plate 250 , and is installed so as to be disposed on one side of the rotating plate 250 facing the first rotation sensing unit 300 . The position of the first sensing object M1 installed in this way may be changed in such a way that it rotates together with the adjustment shaft 194 with the adjustment shaft 194 as the rotation center when the adjustment shaft 194 rotates.

In this embodiment, it is exemplified that the first sensing object M1 is disposed at a position adjacent to the outer circumferential surface of the rotating plate 250 . The position of the first sensing object M1 disposed at such a position may be changed while drawing a trajectory similar to the shape of the outer peripheral surface of the rotating plate 250 when the adjustment shaft 194 rotates.

The first rotation sensing unit 300 is provided to detect a change in the position of the first sensing object M1 , and is disposed between the first sensing object M1 and the valve assembly 190 .

As an example, the first rotation detecting unit 300 may include a supporter 310 , a case 320 , a substrate 330 , and a sensor.

The supporter 310 is fixedly installed to the valve assembly 190 , and the supporter 310 is coupled to the case 320 to support the case 320 . A substrate 330 connected to the controller of the home appliance is installed on the case 320 , and a sensor for detecting a change in the position of the first sensing object M1 is installed on the substrate 330 .

The first rotation detecting unit 300 configured as described above detects the position of the first sensing object M1 in a non-contact manner. To this end, the first sensing object M1 includes a magnetic member that generates a magnetic force, and the first rotation detecting unit 300 includes a hall sensor 340 that detects the magnetic force of a magnetic member close within a predetermined distance. can be done The Hall sensor 340 is installed on the substrate 330 , and when the magnetic member approaches the Hall sensor 340 within a predetermined distance, it detects the magnetic force of the magnetic member and generates a signal corresponding thereto.

According to the present embodiment, the first rotation detecting unit 300 includes a plurality of Hall sensors 340 , and the plurality of Hall sensors 340 are spaced at a predetermined interval along the rotation path of the first sensing object M1 . arranged to be spaced apart.

That is, if the first sensing object M1 rotates while drawing a circular trajectory similar to the shape of the outer peripheral surface of the rotating plate 250 when the adjustment shaft 194 rotates, the first rotation sensing unit 300 has a plurality of Hall sensors 340 ) is arranged in a circular shape corresponding to the rotation trajectory of the first sensing object M1.

In the case of a cooking appliance, when the knob handle 110 is rotated to adjust the opening and closing amount of the valve, the rotation of the adjustment shaft 194 is performed in conjunction with the rotation of the knob handle 110, and the adjustment shaft 194 formed in this way ), an operation for adjusting the opening/closing amount of the valve can be made by the rotation.

For example, when the knob handle 110 is rotated at a predetermined angle from the initial position, the supply of gas through the valve starts. In this state, if the knob handle 110 is further rotated, the supply of gas through the valve is increased. .

As another example, in the case of a household appliance other than a cooking appliance, for example, a washing machine, a dryer, or a dishwasher, the manipulation of the knob handle 110 controls the speed or intensity of an operation performed by the household appliance, or It may be made in a form for selecting a type.

Hereinafter, a case in which the adjustment shaft 194 is rotated by the knob handle 110 and the opening/closing amount of the valve is physically performed by the rotation of the adjustment shaft 194 will be described as an example.

Accordingly, the adjustment shaft 194 rotated by the knob handle 110 rotates a component provided for adjusting the opening/closing amount of the valve in the valve assembly 190 so that the opening/closing amount of the valve is adjusted.

And the rotating plate 250 is also rotated along the rotating adjustment shaft 194 in this way, and the position of the first sensing object M1 is changed in association with the rotation of the rotating plate 250 .

That is, the position of the first sensing object M1 may be changed as much as the adjustment shaft 194 changes the opening/closing amount of the valve. is detected by

For example, assuming that a total of 12 hall sensors 340 are arranged in the first rotation detecting unit 300 at equal intervals, when the knob handle 110 is rotated by 30° from the initial position, 12 As shown in FIG. 14 , the first sensing object M1 positioned closest to any one of the Hall sensors 340 (hereinafter referred to as “No. 0 Hall sensor”) is a No. 0 Hall sensor 340 . The position is changed so that it is located close to another Hall sensor next to it (hereinafter referred to as "No. 1 Hall sensor"). Accordingly, the No. 1 Hall sensor 340 detects the first object M1, and the No. 1 Hall sensor 340 is turned on, and a signal corresponding thereto is transmitted through the No. 1 Hall sensor 340. occurs

And in this state, when the knob handle 110 is rotated by 30°, the first sensing object M1 is placed close to the other Hall sensor (hereinafter referred to as “No. 2 Hall sensor”) next to the No. 1 Hall sensor 340 . The position is changed so as to be located, and accordingly, the first sensing object M1 is detected by the second hall sensor 340 and the second hall sensor 340 is turned on, and the corresponding signal is It is generated through the burn Hall sensor 340 .

In this embodiment, it is exemplified that the first rotation detecting unit 300 includes a plurality of Hall sensors 340 and generates different types of signals for each Hall sensor 340 having a different position. That is, the signal generated by the No. 0 Hall sensor 340, the signal generated by the No. 1 Hall sensor 340, and the signal generated by the No. 2 Hall sensor 340 are all different.

As described above, the signal generated through the hall sensor 340 is information output through the display 123 (refer to FIG. 2 ), for example, the size of the thermal power, the speed or intensity of the operation, the type of operation, etc. It can be provided as basic information for

For example, through the signal generated by the hall sensor 340 No. 1, it can be understood that the knob handle 120 has been manipulated to provide the first-stage thermal power, which is the weakest thermal power, and thus the identified information may be output in the form of characters, designs, or colors through the display 123 .

[Structure of the second sensing object and the second rotation sensing unit]

15 is a view schematically showing the configuration of a second sensing object and a second rotation sensing unit according to an embodiment of the present invention, and FIG. 16 is a view showing a change in position of the second sensing object shown in FIG. 15 .

11, 12 and 15 , the second sensing object M2 is provided to be changed in position by interlocking with the rotation of the support ring 150 , and the second rotation detecting unit 350 is the second sensing object The rotation of the support ring 150 is sensed by detecting a change in the position of (M2), and through this, the rotation of the knob ring 120 connected to the support ring 150 is sensed.

The second sensing object M2 is a configuration to be detected by the second rotation sensing unit 350 and is installed on the support ring 150 . In this embodiment, it is exemplified that the second sensing object M2 is installed on the flange portion 152 of the support ring 150 .

The second sensing object M2 is installed on the flange part 152 , and is installed to be disposed on one side of the flange part 152 facing the second rotation detection part 350 . The position of the second sensing object M2 installed as described above may be changed in a form that is rotated together with the support ring 150 when the support ring 150 is rotated.

In this embodiment, it is exemplified that the second sensing object M2 is disposed at a position adjacent to the outer peripheral surface of the flange part 152 . The position of the second sensing object M2 disposed at such a position may be changed while drawing a trajectory similar to the shape of the outer peripheral surface of the flange portion 152 having a circular shape when the support ring 150 is rotated.

The second rotation sensing unit 350 is provided to detect a change in the position of the second sensing object M2, and is between the second sensing object M2 and the valve assembly 190, more specifically, the second sensing unit. It is disposed between the object M2 and the first sensing object M1.

As an example, the second rotation detecting unit 350 may include a case 360 , a substrate 370 , and a sensor.

The case 360 is fixedly installed on the lower side of the support frame 140 , more specifically, the frame body 141 , and the case 360 has a substrate 370 connected to the controller of the home appliance. is installed

In this embodiment, the substrate 370 is exemplified as being installed on the case 360 and facing the frame body 141 and the second sensing object M2. In addition, a sensor for detecting a change in the position of the second sensing object M2 is installed on the substrate 370 .

The second rotation detection unit 350 configured as described above, like the first rotation detection unit 300 , senses the position of the second detection object M2 in a non-contact manner. To this end, the second sensing object M2 includes a magnetic member that generates a magnetic force, and the second rotation detecting unit 350 includes a hall sensor 380 that detects the magnetic force of a magnetic member close within a predetermined distance. can be done The Hall sensor 380 is installed on the substrate 370 , and when the magnetic member approaches the Hall sensor 380 within a predetermined distance, it senses the magnetic force of the magnetic member and generates a signal corresponding thereto.

According to this embodiment, the second rotation detecting unit 350 includes a plurality of Hall sensors 380 , and the plurality of Hall sensors 380 are spaced at a predetermined interval along the rotation path of the second sensing object M2 . arranged to be spaced apart.

That is, if the second sensing object M2 rotates while drawing a circular trajectory similar to the shape of the outer peripheral surface of the flange part 152 when the support ring 150 is rotated, the second rotation detecting part 350 has a plurality of Hall sensors ( 380 is disposed on the arc corresponding to the rotation trajectory of the second sensing object M2.

In the present embodiment, a pair of Hall sensors 380 are disposed on the second rotation detecting unit 350, and the second sensing object M2 has the knob ring 120 and the support ring 150 in the initial positions. It is exemplified that the Hall sensor 380 and the second sensing object M2 are disposed in a form positioned between the pair of Hall sensors 380 when they are there.

According to this, when the knob ring 120 is rotated in one direction, the second sensing object M2 approaches any one of the pair of Hall sensors 380 (hereinafter referred to as “left Hall sensor”) within a predetermined distance and approaches the corresponding Hall sensor. The second sensing object M2 is sensed at 380, and when the knob ring 120 is rotated in the other direction, the second sensing object M2 is the other one of the pair of hall sensors 380 (hereinafter The second sensing object M2 is sensed by the corresponding Hall sensor 380 by being close to the "right Hall sensor" within a predetermined distance.

When the knob ring 120 is provided to provide a timer function, when the knob ring 120 is rotated in one direction, the second sensing object M2 approaches the left Hall sensor 380 within a predetermined distance and the left Hall sensor ( 380), the detection of the second sensing object M2 is made, and accordingly, the operation of the knob ring 120 for starting the timer operation is detected by the second rotation detection unit 350, and the timer operation is proceeded. may be (see FIG. 16).

In addition, when the knob ring 120 is rotated in the other direction, the second sensing object M2 approaches the right Hall sensor 380 within a predetermined distance, and Sensing is made, and accordingly, the operation of the knob ring 120 for starting the timer operation is sensed by the second rotation detection unit 350, so that the timer operation may proceed.

In this embodiment, it is exemplified that different types of signals are generated for each Hall sensor 380 . That is, the signal generated by the left Hall sensor 380 and the signal generated by the right Hall sensor 380 are both different.

Using this, the function of the knob ring 120 can be configured so that the timer setting time is set differently according to the rotation direction of the knob ring 120 , and different functions can be provided according to the rotation direction of the knob ring 120 . The function of the knob ring 120 may be configured.

As an example, when the knob ring 120 rotates in one direction, the set time of the timer is set in units of 1 minute, and when the knob ring 120 rotates in the other direction, the set time of the timer is set in units of 1 second. ) can be configured.

As another example, the function of the knob ring 120 may be configured such that a timer is set when the knob ring 120 rotates in one direction and the timer setting is released when the knob ring 120 rotates in the other direction.

As another example, the function of the knob ring 120 may be configured such that a timer function is provided when the knob ring 120 is rotated in one direction and a function other than the timer function is provided when the knob ring 120 is rotated in the other direction. may be

Meanwhile, the signal generated through the hall sensor 380 may be provided as basic information for recognizing information output through the display 123 (refer to FIG. 2 ).

For example, by using the signal generated from the left Hall sensor 340 as basic information, information such as whether a timer starts or not, a timer time, etc. may be identified, and the determined information may be displayed as text or text through the display 123 . It can be printed in the form of a design or color.

*

[Action, effect of knob knob and knob ring rotation detection structure]

11 and 12 , the rotation detection of the knob handle 110 is performed in a non-contact manner using the first detection object M1 and the first rotation detection unit 300 , and the rotation of the knob ring 120 is performed. Sensing may be performed in a non-contact manner using the second sensing object M2 and the second rotation sensing unit 350 .

In this case, the rotation centers of the first sensing object M1 and the second sensing object M2 are arranged in a line along one axis, that is, the adjustment axis 194 . In addition, the first rotation detection unit 300 provided to detect the position of the first detection object M1 is also disposed on the same axis as the rotation of the first detection object M1 and the second detection object M2. The center and the first rotation detecting unit 300 are arranged in a line along one axis.

In order to design the structure of the knob assembly in such a way that they are arranged in a line along the control shaft 194, transmission of rotational force for adjusting the opening/closing amount of the valve and transmission of rotational force for changing the position of the first sensing object M1 This should be done by one adjustment shaft 194, and the first rotation detection unit 300 can pass the adjustment shaft 194 while effectively detecting a change in the position of the first sensing object M1. should be provided In addition, the configuration provided to rotate the second sensing object M2, that is, the support ring 150 must be provided to allow the adjustment shaft 194 to pass therethrough.

According to the present embodiment, the adjustment shaft 194 sequentially passes from the knob handle 110 through the support ring 150 , the rotation plate 250 on which the first sensing object M1 is installed, and the first rotation sensing unit 300 . Thus, by being connected to the valve assembly 190 , a rotational force for adjusting the opening/closing amount of the valve may be transmitted to the valve assembly 190 . And as described above, the adjustment shaft 194 installed to connect between the knob handle 110 and the valve assembly 190 is rotated to transmit a rotational force for adjusting the opening/closing amount of the valve, and the position of the first sensing object M1 is also shown. can change together.

That is, only by providing one adjustment shaft 194, both the action of the shaft required to transmit the rotational force for adjusting the opening and closing amount of the valve and the action of the shaft required to sense the rotational position of the knob handle 110 can be provided. there will be

The design of this structure is possible because the rotation of the knob handle 110 made of a combination of the first sensing object M1 and the first rotation sensing unit 300 is sensed in a non-contact manner.

In order to transmit the rotational force for adjusting the opening/closing amount of the valve, a physical connection between the control shaft 194 and the valve is inevitably required. Therefore, if the rotation detection device is configured in such a way that a physical connection between the adjustment shafts 194 is required to detect the rotation of the knob handle 110 , additional power for transmitting the rotational force of the adjustment shaft 194 to the rotation detection device A delivery structure is required.

For example, if the rotation sensing device for detecting the rotation of the knob handle 110 is configured in a form including an encoder, a separate rotation shaft for transmitting the rotational force of the adjustment shaft 194 to the encoder and adjustment with this rotation shaft A configuration of gears for connecting the shafts 194 should be added.

However, when a power transmission structure including a separate rotating shaft and gears is added as described above, parts and assembly processes are added and manufacturing costs are increased, and a difficult process to satisfy gear backlash is added, which can increase the difficulty of manufacturing operations. there is. In addition, during repeated use, a problem in that the error of the detection result increases due to wear of the gear, a change in the meshing state of the gear, etc. may occur.

In contrast, in the rotation detection structure of the knob handle 110 of the present embodiment, the rotation detection of the knob handle 110 is made in a non-contact manner, and only having one adjustment shaft 194 is used to control the opening/closing amount of the valve. Since both the action of the shaft required to transmit the rotational force and the action of the shaft necessary to detect the rotational position of the knob handle 110 can be provided, an additional power transmission structure for transmitting the rotational force of the adjustment shaft 194 to the sensing device is provided. no need to add

In addition, since the rotation detection of the knob ring 120 is performed in a non-contact manner even in the structure of detecting the rotation of the knob ring 120 of this embodiment, it is necessary to add an additional power transmission structure for transmitting the rotation of the knob ring 120 to the sensing device there is no

Accordingly, the knob assembly of this embodiment and the home appliance having the same provide a function of simultaneously performing a physical power transmission operation through manipulation of the knob handle 110 and a sensing operation for sensing manipulation of the knob handle 110, It is possible to suppress the increase in the parts and assembly process and manufacturing cost required for realization of the function, and to make the manufacturing operation easier, and to control the operation of the operation switch such as the knob handle 110 and the knob ring 120 . It can provide the effect of effectively improving the sensing performance.

[Rotation detection method of rotation detection device]

Hereinafter, a rotation sensing method of the rotation sensing device will be described in detail. In this embodiment, the rotation detecting device is defined as a configuration for detecting manipulation of the knob handle 110 , that is, a configuration including the first sensing object M1 and the first rotation detecting unit 300 .

17 is a block diagram schematically showing the configuration of a rotation sensing device according to an embodiment of the present invention, and FIG. 18 is a flowchart showing a knob rotation sensing process of the rotation sensing device according to an embodiment of the present invention. Also, FIG. 19 is a view showing a second example of the position change state of the first sensing object, FIG. 20 is a view showing a third example of the position change state of the first sensing object, and FIG. 21 is an embodiment of the present invention It is a flowchart showing a signal selection process for generating an operation control signal of the rotation sensing device according to

The knob rotation detection of the rotation detection device according to an embodiment of the present invention may be performed in the following way.

13, 17 and 18, when the knob handle located at the initial position is rotated by a predetermined angle, the first sensing object M1 located on the No. 0 Hall sensor 340 side is rotated along the knob handle. The position is changed, and the position of the first sensing object M1 is detected by the Hall sensor 340 closest to the first sensing object M1.

For example, when the presence of the first sensing object M1 is detected by the Hall 1 sensor 340, the Hall sensor No. 1 340 is turned on, and a signal corresponding thereto is It is generated through the sensor 340 .

The signal generated in this way is received by the control unit 400 (S10), and the control unit 400 receiving this signal determines the type of the received signal (S20). According to the present embodiment, since different types of signals are generated for each hall sensor 340 having a different position, the signal received by the control unit 400 is transmitted to the plurality of holes by identifying the type of the signal received by the control unit 400 . The signal generated by which hall sensor 340 among the sensors 340 can be easily identified, and through this, the degree of rotation of the knob handle can be easily identified.

When the type of the received signal is identified, the control unit 400 generates an operation control signal corresponding to the identified signal type (S50).

As an example, the operation control signal may be generated as a signal for controlling the operation of the display 123 . According to this, the operation control signal generated according to the type of the identified signal is transmitted to the display unit 123, and the display unit 123 receiving the operation control signal receives the size of the thermal power adjusted through the rotation of the knob handle, etc. The same information can be output.

As another example, when the valve is controlled by electronically controlling the opening/closing amount of the valve based on the result of measuring the rotation of the knob handle, the operation control signal is a signal for controlling the operation of the display 123 . In addition, it may be generated as a signal for controlling the opening/closing amount of the valve.

On the other hand, as shown in FIGS. 17 to 19 , even when the position change of the first sensing object M1 is made at a very high speed by turning the knob handle located at the initial position at a high speed, the first sensing object M1 The position of can be accurately detected by the Hall sensor 340 closest to the first sensing object M1.

The rotation detecting device of the present embodiment configures absolute coordinates in a manner that generates different types of signals for each Hall sensor 340 having a different position, and uses the absolute coordinates configured as described above for the first sensing object Detect the position of (M1).

That is, regardless of where the immediately preceding position of the first sensing object M1 was, if the signal finally received by the control unit 400 is a signal generated by the No. 1 Hall sensor 340, the position of the first sensing object M1 is The position of the first sensing object M1 is detected as being a position corresponding to the first Hall sensor 340 area, and if the signal finally received by the control unit 400 is a signal generated by the seventh hall sensor 340 , the position of the first sensing object M1 It is sensed as a position corresponding to the 7th Hall sensor 340 area.

Therefore, no matter how fast the rotation of the knob handle is, the final position of the first sensing object M1 in the state where the rotation of the knob handle is completed is accurately detected, and thus the rotation angle of the knob handle can be accurately determined. there will be

If the rotation detecting device detects the position of the first sensing object M1 in a manner using relative coordinates, which is a method of detecting a change in position from the immediately preceding position of the first sensing object M1, the knob handle When is rotated at a very high speed, a phenomenon in which the position of the sensing object M1 is not properly detected may occur.

That is, if the knob knob is turned at a very high speed in a state where the first sensing object M1 is located at the position corresponding to the No. 1 Hall sensor 340 area, the second sensor located at the location corresponding to the No. 1 Hall sensor 340 area is turned. The first sensing object M1 passes through a location corresponding to the area of the other Hall sensors 340 adjacent to the No. 1 Hall sensor 340 at a very high speed, and in this process, some Hall sensors 340 that were in the passage path ), a phenomenon in which detection of the first sensing object M1 is not performed may occur.

For example, in order to properly detect the position of the first sensing object M1 that has moved from the position corresponding to the No. 1 Hall sensor 340 area to the location corresponding to the No. 7 Hall sensor 340 area, a total of six Hall sensors The ON state change of 340 should be sequentially performed, but the ON state change of some hall sensors 340 cannot be made due to the position of the first sensing object M1 being changed at a very high speed. Positioning of the first sensing object M1 is not properly performed.

In this case, the rotation detecting device grasps the position of the first sensing object M1 as a position corresponding to the region between the second hall sensor 340 and the sixth hall sensor 340, or the knob handle is rotated at all. An error of recognizing that it is not supported occurs.

In contrast, the rotation sensing device of the present embodiment senses the position of the first sensing object M1 using absolute coordinates configured in a manner of generating different types of signals for each Hall sensor 340 having a different position.

The rotation detection device of this embodiment accurately detects the final position of the first sensing object M1 in a state in which the rotation of the knob handle is completed regardless of the rotation speed of the knob handle, thereby accurately determining the rotation angle of the knob handle. , so that an accurate control operation corresponding to the manipulation of the knob handle can be made.

Meanwhile, according to the rotation detection method of the present embodiment, when two or more types of signals are simultaneously received or no signal is received after the knob knob and the control shaft connected thereto are rotated, signal selection for selecting any one of the received or received signals It may further include a step (S30).

Occasionally, the knob handle is manipulated so that the first sensing object M1 is positioned between two adjacent hall sensors 340 (see FIG. 20 ). In this case, the first sensing object M1 may be detected by both Hall sensors 333 located on both sides of the first sensing object M1, and the first sensing object M1 is both detected by the two Hall sensors 340 . It may not be possible to detect for (M1).

When such a situation occurs, since two types of signals are simultaneously received or no signals are received by the control unit 400, the rotation of the present embodiment for determining the position of the first sensing object M1 in a manner using absolute coordinates Due to the characteristics of the sensing device, it is difficult to properly grasp the position of the first sensing object M1.

In consideration of this problem, in the present embodiment, when two or more types of signals are simultaneously received or no signal is received after the knob knob and the control shaft connected thereto are rotated, signal selection for selecting any one of the received or received signals Step S40 may be added.

According to this embodiment, in the signal selection step (S40), when two or more types of signals are simultaneously received, a previously received signal is selected from among the received signals, and no signal is received after the knob knob and the control shaft connected thereto are rotated. Otherwise, it may be implemented in the form of selecting a signal received immediately before it.

As an example, the knob handle is manipulated so that the first sensing object M1 is positioned between the 6th Hall sensor 340 and the 7th Hall sensor 340, and at this time, the 6th Hall sensor 340 and the 7th hall When both of the sensors 340 are in an ON state and two types of signals are simultaneously received, the control unit 400 selects the signal of the 6th hall sensor 340, an operation control signal set in response to the selected signal, For example, an operation control signal for outputting the number “6” to the display 123 may be generated.

As another example, the knob handle is operated so that the first sensing object M1 is positioned between the 6th Hall sensor 340 and the 7th Hall sensor 340, and at this time, any Hall sensor 340 is turned ON. ) state, the control unit 400 may select the signal received immediately before that, that is, the signal of the 6th Hall sensor 340, and generate an operation control signal set in response to the selected signal.

In this way, even in a state in which the position of the first sensing object M1 is difficult to be accurately detected, the rotation angle of the knob handle can be stably grasped, thereby providing information such as the amount of thermal power adjusted through the rotation of the knob handle. The operation control for outputting , or the operation control for controlling the opening/closing amount of the valve can be performed stably without interruption.

If there is no area in which the detection of the first object M1 is not performed between the plurality of Hall sensors 340, that is, at least one Hall sensor 340 is turned on no matter where the first object M1 is located. If the sensing area of the Hall sensor 340 is adjusted to be in the (ON) state, when neither Hall sensor 340 is in the ON state, the controller 400 controls at least one of the Hall sensors 340 It may recognize that a failure or operation error has occurred, and generate an operation control signal related thereto.

On the other hand, the rotation sensing device of the present embodiment may be configured to further include an auxiliary sensing unit 450 .

The auxiliary sensing unit 450 is provided auxiliary to detect whether the adjustment shaft is rotated to a position deviated from the initial position, that is, whether the knob handle is rotated. That is, the auxiliary sensing unit 450 does not need to be configured to detect how much rotation of the knob handle is made, it is sufficient if it is configured to detect only whether the rotation of the knob handle is made.

In this embodiment, the auxiliary sensing unit 450 is exemplified to include a mechanical switch that is turned on or off while the connection state between the contacts is changed by the rotational force transmitted through the adjustment shaft.

As described above, the auxiliary sensing unit 450 including the mechanical switch is provided in the form of being turned on/off through a mechanical force transmitted through the control shaft, rather than being operated in an electronic manner. It is possible to reliably detect whether the knob handle is rotated in a state free from the influence of noise that affects the operation.

If the rotation of the knob handle is not detected due to a malfunction or malfunction of the first rotation detection unit 300 even though the knob handle is rotated and gas is supplied through the valve, gas leakage The risk of a major fire accident increases.

In consideration of this, the rotation detection device of this embodiment further includes a mechanical switch type auxiliary detection unit 450 capable of detecting only whether the knob handle has been rotated, and through this, the first rotation detection unit 300 Even if rotation of the knob handle is not detected by the

As an example, the auxiliary sensing unit 450 is in an OFF state in a state in which the knob handle is not rotated, that is, in a state in which the knob knob is in the initial position, and is in an ON state when the knob knob is rotated. It may be provided in a form that is changed to .

The state change of the auxiliary sensing unit 450 is monitored by the control unit 400 , and the information on the state change of the monitored auxiliary sensing unit 450 is determined as to whether the first rotation detecting unit 300 is faulty. And as a result, it may be used as information for determining whether to perform control for a subsequent operation related to the output and control for a subsequent operation related to blocking gas leakage.

According to the rotation sensing method of the rotation sensing device further including the auxiliary sensing unit 450 as described above, as shown in FIGS. 17 to 21 , receiving a signal generated by the auxiliary sensing unit 450 ( S50 ). ) may be further included.

In this step, a signal related to information on whether the auxiliary sensing unit 450 is in an ON state or an OFF state is received by the control unit 400, and the control unit 400 receiving this signal is a Hall sensor ( 340) and the signal of the auxiliary sensing unit 450 are comprehensively considered to generate a motion control signal corresponding thereto.

Below, if the hall sensor 340 is defective, the corresponding hall sensor 340 continuously maintains an ON state regardless of whether the first sensing object M1 is detected, and if the auxiliary sensing unit 450 is defective, A case in which the corresponding auxiliary sensing unit 450 continuously maintains an ON state regardless of whether the knob handle is rotated will be described as an example.

As a first example, the control unit 400 that receives the signal of the hall sensor 340 and the signal of the auxiliary sensing unit 450 together, any one of the plurality of hall sensors 340 is in an ON state and auxiliary sensing When the unit 450 is in an ON state, it is possible to generate an operation control signal corresponding to the type of signal of the hall sensor 340 in the ON state.

For example, when the 7th hall sensor 340 is in an ON state, the control unit 400 generates an operation control signal for outputting information indicating that the heating power of the cooking appliance is “7” to the display 123 . can

As a second example, in the controller 400 receiving the signal of the hall sensor 340 and the signal of the auxiliary sensing unit 450 together, two of the plurality of hall sensors 340 are in an ON state and the auxiliary sensing unit When 450 is in an ON state, an operation control signal corresponding to one selected signal among signals received from the hall sensors 340 in an ON state may be generated.

For example, when the 6th Hall sensor 340 and the 7th Hall sensor 340 are in an ON state, the control unit 400 selects the signal of the 6th Hall sensor 340 and responds to the selected signal. A set operation control signal, for example, an operation control signal for outputting the number “6” to the display 123 may be generated.

As a third example, in the controller 400 receiving the signal of the hall sensor 340 and the signal of the auxiliary sensing unit 450 together, at least one of the plurality of hall sensors 340 is in an ON state and When the sensing unit 450 is in an OFF state, an operation control signal set in relation to the state of the hall sensor 340 is generated.

For example, if the auxiliary sensing unit 450 is in an OFF state and the 6th Hall sensor 340 is in an ON state, the control unit 400 displays an error message indicating that the 6th Hall sensor 340 is defective. It is possible to generate an operation control signal for output.

As a fourth example, the control unit 400 receiving both the signal of the hall sensor 340 and the signal of the auxiliary sensing unit 450 may assist while none of the plurality of hall sensors 340 is in an ON state. When the sensing unit 450 is in an ON state, an operation control signal set in relation to the state of the auxiliary sensing unit 450 is generated.

That is, when the rotation of the knob handle is not detected in the first rotation detection unit 300 and the rotation of the knob handle is detected only in the auxiliary detection unit 450 , the control unit 400 sends an error message indicating that the auxiliary detection unit 450 is defective. Generates an operation control signal for outputting .

Of course, the operation control signal generating operation of the control unit 400 is such that there is no area in which the first sensing object M1 is not detected between the plurality of hall sensors 340 , that is, the first sensing object M1 is It may be made under the condition that the sensing area of the Hall sensor 340 is adjusted so that at least one Hall sensor 340 is in an ON state even in the position.

According to the rotation detection method of this embodiment made as described above, the auxiliary detection unit 450 provided to detect whether the knob handle is rotated is used to determine whether to perform the control for the subsequent operation related to blocking the gas leakage. In addition to being able to receive information, it is possible to secure information for determining whether the hall sensor 340 has an operation error or malfunction.

As a result, the rotation detection device of this embodiment can contribute to significantly reducing the risk of fire due to gas leakage, and information on whether the components for detecting the rotation of the knob handle are defective or not can be quickly and accurately secured. In this case, it is possible to provide an effect of providing a reliable detection result because a malfunction due to noise or error of an electronic component is prevented.

Although the present invention has been described with reference to the embodiment shown in the drawings, this is merely exemplary, and it is understood that various modifications and equivalent other embodiments are possible by those of ordinary skill in the art. will understand Accordingly, the true technical protection scope of the present invention should be defined by the following claims.

110: knob knob
120: knob ring
121: closing cap
122: display housing
123: display
124: knob ring body
125: back plate
125b: support plate
125c: support hole
126: support pipe
126d: support grain
126c: support
126b: tapered tube
126a: flange
130: bearing shell
132: disc part
134: cylindrical part
140: support frame
141: frame body part
143: pass hole
145: support
147: first frame side coupling part
148: second frame side coupling part
150: support ring
151: coupling shaft portion
152: flange part
153: wing
155: wing side coupling part
160: fixed frame
161: fixed part
163: wing insert
190: valve assembly
194: adjustment axis
194a: valve shaft
194b : knob axis
200: burner frame
210: guide rod
250: rotating plate
300: first rotation detection unit
310: supporter
320,360 : Case
330,370: substrate
340,380: Hall sensor
350: second rotation detection unit
400: control unit
450: auxiliary sensing unit
M1: first sensing object
M2: second sensing object
S1: first elastic member
S2: second elastic member

Claims (9)

a first sensing object installed on an adjustment shaft that is rotated in association with the rotation of the knob handle and whose position is changed in association with the rotation of the adjustment shaft;
a first rotation detecting unit configured to sense a change in the position of the first sensing target in a non-contact manner that does not come into contact with the first sensing target;
an auxiliary sensing unit for detecting whether the adjustment shaft is rotated to a position deviated from the initial position; and
A control unit for generating an operation control signal based on the detection result of the first rotation detection unit and the auxiliary detection unit;
The first rotation detection unit includes a plurality of sensors that are spaced apart from each other along the rotation path of the first detection object and generate a signal when the first detection object is turned on by detecting the first detection object,
generating a different kind of signal for each said sensor having a different position,
The control unit receives the signals generated by the sensor and the auxiliary sensing unit, and generates an operation control signal set in response to the type of the received signal or an operation control signal set in relation to the state of the sensor, When at least one of the sensors is in an ON state and the auxiliary sensing unit is in an OFF state, a rotation sensing device for generating an operation control signal set in relation to the state of the sensor.
According to claim 1,
The auxiliary sensing unit includes a mechanical switch that is turned on or off by changing the connection state between the contacts by the rotational force transmitted through the control shaft.
According to claim 1,
When at least one of the plurality of sensors is in an ON state and the auxiliary sensing unit is in an ON state, the control unit performs an operation set in response to a received signal or a signal selected from among the received signals A rotation sensor that generates a control signal.
According to claim 1,
The control unit, when none of the plurality of sensors is in an ON state and the auxiliary sensing unit is in an ON state, the control unit generates an operation control signal set in relation to the state of the auxiliary sensing unit.
A home appliance comprising the rotation sensing device of any one of claims 1 to 4.
As a rotation detection method of the rotation detection device of claim 1,
a signal receiving step of receiving a signal generated by the sensor;
A signal grasping step of recognizing the type of the received signal; and
A rotation detection method comprising a control signal generating step of generating an operation control signal corresponding to the identified signal type.
7. The method of claim 6,
Further comprising the step of receiving a signal generated by the auxiliary sensing unit,
In the control signal generating step, when at least one of the plurality of sensors is in an ON state and the auxiliary sensing unit is in an ON state, it corresponds to a received signal or a signal selected from among the received signals. A rotation detection method to generate a set motion control signal.
7. The method of claim 6,
Further comprising the step of receiving a signal generated by the auxiliary sensing unit,
In the control signal generating step, when at least one of the plurality of sensors is in an ON state and the auxiliary sensing unit is in an OFF state, a rotation detection method for generating an operation control signal set in relation to the state of the sensor .
7. The method of claim 6,
Further comprising the step of receiving a signal generated by the auxiliary sensing unit,
In the control signal generating step, if none of the plurality of sensors is in an ON state and the auxiliary sensing unit is in an ON state, rotation detection for generating an operation control signal set in relation to the state of the auxiliary sensing unit Way.

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