RU2653098C1 - Refrigerator - Google Patents

Abstract

FIELD: refrigerating equipment.

SUBSTANCE: invention relates to configurations of operating displays of refrigerators. Refrigerator includes working display panel (6) including transparent element (11), transparent sheet electrode (12) located on the rear side of transparent element (11), support member (13), which supports transparent sheet electrode (12) and electronic substrate (14) including plurality of light sources (25) and a microcomputer. Transparent sheet electrode (12) includes transparent base material (18), transparent conductive paint layer (20) located on the surface of transparent base material (18), facing transparent element (11), printed layer (22) of notations, located on the surface of transparent material (18) of the base on the side of electronic substrate (14), and layer (19) of rigid wiring, which connects transparent conductive paint layer (20) to electronic substrate (14).

EFFECT: refrigerator has a display, formed with a reduced number of elements, and has improved performance, reduced cost and stable quality, even when the working display provides surface emission.

9 cl, 15 dwg

Description

FIELD OF THE INVENTION

[0001] The invention relates to refrigerators and, more particularly, to configurations of operating displays of refrigerators.

BACKGROUND OF THE INVENTION

[0002] In recent years, refrigerators typically have a touch screen operation display (work display panel). The working display is usually configured to display a touch-sensitive working part, signs or signs with improved visibility due to the emission of light by a light source.

[0003] In addition, the touch working part of the working display also has an energy saving function, so that the touch working part is usually turned off when not working and turned on only when it is working.

[0004] For older users, a certain size of the light emitting region for the sensory working part, the image and character display part is desirable. Therefore, a number of optical fibers are often used to provide surface emission (for example, see Patent Literature 1).

List of Contrasted Materials

Patent Literature

[0005] Patent Literature 1: Registration No. 3172080 utility model

A brief description of the present invention

Technical problem

[0006] When using a number of light guides to provide surface emission, a light guide is required for each of the sensory working part, a part for displaying signs and signs (for example, 30 light guides are necessary for 30 elements to be illuminated). Such an increase in the number of elements is the cause of poor performance, increased cost and unstable quality.

[0007] The invention seeks to overcome the above problems, and an object of the present invention is to provide a refrigerator having an operation display formed with a reduced number of elements and having increased productivity, reduced cost and stable quality even when the operation display provides surface emission.

Solution

[0008] A refrigerator in accordance with an embodiment of the present invention is a refrigerator that includes a transparent plate element, a multilayer sheet located on the rear side of the transparent plate element and configured to detect at least a change in capacitance, and an electronic substrate located on the side of the multilayer sheet opposite the transparent plate element, and the electronic substrate includes many light sources, made with the possibility Strongly light emission on a multilayer sheet, and includes a controller configured to receive a signal detected by a multilayer sheet, as a working signal, and controlling the plurality of light source for emitting light. The multilayer sheet includes a transparent base material, a plurality of transparent conductive elements located on the surface of the transparent base material facing the transparent plate element and configured to detect a change in capacitance, a light shielding layer located on the surface of the transparent base material on the side of the electronic substrate, and includes a pattern configured to display the shape of at least one of the signs and symbols, and a light scattering layer, laid on the surface of the light-shielding light on the side of the electronic substrate and configured to scatter light emitted from multiple light sources.

The positive results of the present invention

[0009] In the refrigerator in accordance with an embodiment of the present invention, the aforementioned configuration of the operation display provides a significant reduction in the number of elements of the operation display, thereby achieving improved productivity, reduced cost and stable quality.

Brief Description of the Drawings

[0010] FIG. 1 is a front view of a refrigerator in accordance with a first embodiment of the present invention;

figure 2 is a view in section of the refrigerator in figure 1;

figure 3 is a perspective view with a spatial separation of the elements of the panel of the working display in figure 1;

figure 4 - detailed views of the elements of the panel of the working display in figure 3, where (a) depicts a transparent sheet electrode and a support element, and (b) shows a support element and an electronic substrate;

5 is an external view of a transparent sheet electrode in figure 3;

6 is a view in section of a transparent sheet electrode in figure 5;

Fig.7 is a view in section of the panel of the working display in Fig.1;

Fig. 8 is an external view of a transparent sheet electrode in accordance with a second embodiment of the present invention;

Fig.9 is an external view of a transparent sheet electrode in accordance with the modification example in Fig.8;

figure 10 is a view in section of the panel of the working display, including a transparent sheet electrode in figure 9;

11 is a view in section of the panel of the working display in accordance with a third embodiment of the present invention;

Fig is a perspective view with a spatial separation of the elements of the panel of the working display in accordance with the fourth embodiment of the present invention;

Fig.13 is a detailed view of the connecting part of the connector panel of the working display in Fig.12;

Fig is a perspective view with a spatial separation of the elements of the panel of the working display in accordance with the fifth embodiment of the present invention; and

15 is a front view of a refrigerator in accordance with a fifth embodiment of the present invention.

[0011] First Embodiment

1 is a front view of a refrigerator in accordance with a first embodiment of the present invention.

As shown in FIG. 1, refrigerator 1 includes a refrigerator compartment 100, a switch compartment 200, an ice maker compartment 300, a freezer compartment 400, and a vegetable compartment 500. The refrigerator compartment 100 has an openable door and is located in the upper position. The switching compartment 200 has a drawer door and is positioned below the refrigerating compartment 100. The switching compartment 200 can be switched from the freezing temperature range (-18 ° C), for example, to the cooling temperature range (3 ° C), the reduced temperature interval (0 ° C) or the temperature range of slight freezing (-7 ° C). The ice maker compartment 300 has a drawer door and is parallel to the switching compartment 200. The freezer compartment 400 has a drawer door and is positioned under the switching compartment 200 and the ice maker compartment 300. The vegetable compartment 500 has a drawer door and is located in the lower position.

[0012] The operation display panel 6 is located on the front surface of the door of the refrigerator compartment 100. The operation display panel 6 includes operation mode switches that adjust the temperatures and settings of the respective compartments, parts of the display that display the temperature or other parameter of the respective compartments, and other sections . The panel 6 of the working display may be located inside the refrigerator 1, for example, on the side surface of the refrigerator compartment 100. In addition, the configuration of the refrigerator 1 is not limited to the configuration shown in figure 1. For example, the refrigerator 1 may not include a switch compartment 200 and an ice maker compartment 300, or may have a freezer compartment 400 and a vegetable compartment 500 in positions opposite to those shown in FIG.

[0013] FIG. 2 is a cross-sectional side view of the refrigerator 1 of FIG. 1.

As shown in FIG. 2, the refrigerator 1 includes a compressor 2, a cooling device 3, and a blower fan 4. A blower fan 4 delivers cooled air cooled by the cooling device 3 to the respective compartments of the refrigerator 1 through a flow channel 5. A flow channel 5 is provided for supplying chilled air cooled by the cooling device 3 to respective compartments. That is, the cooled air cooled by the cooling device 3 passes through the flow channel 5 to the freezing compartment 400, the switching compartment 200, the ice maker compartment 300 and the refrigerating compartment 100 to cool these compartments. The exhausted cooled air from the refrigeration compartment 100 circulates through a return flow channel (not shown) of the refrigeration compartment to cool the vegetable compartment 500 and then returns to the cooling device 3 through the return flow channel (not shown) of the vegetable compartment. The temperature of each compartment is determined by a thermistor (not shown) located in each compartment and is adjusted to set the desired temperature by adjusting the degree of opening of the damper (not shown) located in the flow channel 5, the operation of the compressor 2 and due to the amount of air supplied by the blower fan 4 .

[0014] In the freezer compartment 400, the accommodating chamber 401 is configured to store food. In the switching compartment 200, the accommodation chamber 201 is configured to store food products. In the vegetable compartment 500, a storage chamber 501 is configured to store food. Each compartment may include a single chamber or, alternatively, may include two or more chambers to enhance order when the entire volume of the refrigerator 1 is large.

[0015] Next, the configuration of the operation display panel 6 will be described.

Figure 3 is a perspective view with a spatial separation of the elements of the panel 6 of the working display. 4 is a detailed view of the panel 6 of the working display in figure 3, and (a) shows a transparent sheet electrode 12 and the support element 13, and (b) shows the support element 13 and the electronic substrate 14. The panel 6 of the working display consists of a capacitive tactile a sensor that works by detecting a change in capacitance. In addition, the transparent sheet electrode 12 is a multilayer sheet formed of layers, each layer having a function, and corresponds to a "multilayer sheet" of the present invention.

[0016] In FIGS. 3 and 4, the operation display panel 6 consists of approximately five elements, which are a transparent element 11, a transparent sheet electrode 12, a support element 13 that supports a transparent sheet electrode 12, an electronic substrate 14 including a microcomputer and a light source 25, and a holding member 15 that holds these elements. The material of the transparent element 11 is not limited, provided that the material is glass, resin or other transparent and light-transmitting material and can be made in the form of a structural element, decorated with printing or using another process, provided that the material transmits light emitted by the light source 25. The support element 13 also performs the function of a light-shielding wall that insulates light between adjacent designations. In addition, although an inexpensive light emitting diode is often used as the light source 25, a different type of light source may be used. The transparent element 11 forms part of the door of the refrigerator 1 and corresponds to the “transparent plate element” of the present invention. The support member 13 supports the transparent sheet electrode 12 and corresponds to the “support member” of the present invention. A microcomputer (not shown) receives a signal detected by the transparent sheet electrode 12 as a control signal, controls a plurality of light sources 25 to emit light, and corresponds to a “controller” of the present invention.

[0017] Next, a transparent sheet electrode 12 will be described.

5 is an external view of the transparent sheet electrode 12, and FIG. 6 is a sectional view of the transparent sheet electrode 12. Although all display elements of the transparent sheet electrode 12 are shown in FIG. 5, only the power button 16 is shown in the initial position. When you touch the button 16 to enable the transparent sheet electrode 12, the designations of 17 operating modes are displayed (turn on). For convenience, the image of figure 5 is depicted with an inverted black and white image. The same image is also used in FIGS. 8 and 9.

[0018] In a sectional view of the transparent sheet electrode 12, the transparent backing material 18 is located in the center, and the hard wiring layer 19, the transparent conductive paint layer 20 and the paint insulating layer 21 are formed on the front surface (working side) of the transparent backing material 18, and printed a designation layer (light-protective layer) 22, a light-scattering printing layer 23, and an adhesive printing layer 24 are formed on the back surface (substrate side) of the transparent base material 18. By fixing the transparent sheet electrode 12 having the aforementioned configuration on the support member 13, the transparent sheet electrode 12 is supported by the support member 13. The transparent conductive ink layer 20 is printed at the position of the power button 16, and the transparent conductive ink layer 20, the printing marking layer 22 and the light scattering printing layer 23 printed in the positions of the designations of the operating modes. The hard wiring layer 19 is a color wiring pattern that connects the transparent conductive paint layer 20 and the electronic substrate 14 to each other. The hard wiring layer 19 includes a plurality of mounting wires spaced parallel to each other, and corresponds to a “plurality of mounting wires” of the present invention. The transparent conductive paint layer 20 determines the change in capacitance and corresponds to the “plurality of transparent conductive elements” of the present invention. The printing layer (light protection layer) 22 of the designation has a pattern for displaying a variety of forms, such as signs or symbols (see FIG. 5), and corresponds to the “light protection layer” of the present invention. The light scattering print layer 23 scatters the light emitted by the light source 25 and corresponds to the “light scattering layer" of the present invention.

[0019] FIG. 7 is a sectional view of the operation display panel 6 and depicts all elements of the operation display panel 6.

When displaying (turning on) the designation symbol 17, the light source 25 emits light through the transparent conductive paint layer 20, the printing symbol layer 22, the light diffusing printing layer 23 and the transparent element 11 for displaying the symbol, which should be visible. In addition, by touching the symbol 17 of the operating mode, the operating mode is activated. A light source 25 is located for each of the power button 16, designations 17 of operation modes and letters (characters) on the printed designation layer 22, and the light-scattering printing layer 23 is also configured to provide surface emission for each of the designations or characters.

[0020] The light scattering printing layer 23 is printed on a transparent sheet electrode 12 to diffuse the light emitted by the light source 25, thereby providing surface emission. Therefore, large signs or signs can be displayed due to uniform light without the use of an element such as a light guide.

[0021] Furthermore, by using a white or similar color support element 13, the reflected light from the light source 25 can be effectively used for signs, thereby improving visibility. In this case, when using a transparent element instead of a white or similar colored element, the light from the light source 25 can be partially transmitted through the supporting element 13, and adjacent symbols may be erroneously illuminated. To prevent light from being transmitted to adjacent symbols, a double wall 26 may be formed on the support member 13. The double wall 26 corresponds to the “light barrier wall” of the present invention.

[0022] As described in the first embodiment, a transparent conductive paint layer 20 that determines the change in capacitance, a hard wiring layer 19 that transfers the change in capacitance to the electronic substrate 14, a designation print layer 22 that uses the light emitted from the light source 25 to display designations, and the light-scattering printing layer 23, which uses light to provide surface emission, is jointly printed on a single transparent material (film backing material) 18 backing, as shown in the view in zreze transparent flat electrode 12 in Figure 6, thus greatly reducing the number of elements compared to the number of elements of the prior art. As a result, reducing the number of elements can increase productivity, reduce costs and ensure consistent quality.

[0023] Moreover, since the symbols and letters (signs) are displayed by the light source 25 emitting light through the transparent element 11, the operation display panel 6 provides good visibility and ease of use for users of all ages. In addition, the shapes of the transparent sheet electrode 12 and the support member 13 must be designed so that a surface emission equal to or greater than the surface emission using the light guide can be achieved, providing improved visibility without increasing the number of elements. The transparent element 11 can also be made in the form of a decorated designed element that forms part of the door of the refrigerator 1.

[0024] Second Embodiment

Fig. 8 is an external view of a transparent sheet electrode 12 in accordance with a second embodiment of the present invention.

Although the hard wiring layer 19 may have different wiring patterns, the wiring for the power button 16 will be described as an example. When the wiring of the power-on button 16 is made as a single wire 27, the power-on button 16 may respond when a finger touches the wiring area, leading to an erroneous operation mode. Since a single wire reduces stray capacitance, the wiring area, as well as the transparent conductive paint layer 20 become very sensitive and can cause the button 16 to react.

[0025] In the second embodiment, as shown in FIG. 8, the composite wire 28 is assembled on one side together with the other hard wiring group 29 consisting of a plurality of parallel wires assembled together in parallel. As a result, the stray capacitance of the wiring area of the power button 16 is less sensitive than the wiring area of a single wire, thereby preventing erroneous operation of the power button 16. Thus, erroneous operation of the buttons can be prevented by assembling the wiring groups together. This wiring configuration can also be used for operation buttons other than the power button 16.

[0026] FIG. 9 is a view of an example of a modification of the transparent sheet electrode of FIG. 8, and FIG. 10 is a sectional view of the operation display panel 6 including the transparent sheet electrode 12 of FIG. 9.

As shown in FIG. 9, a portion of the transparent sheet electrode 12 (and the transparent base material 18) extends to the left side. Then, a single wire 27 of the power button 16 is laid on an extended portion. In addition, as shown in FIG. 10, the extended portion of the transparent sheet electrode 12 is bent along the support member 13 to be secured to the support member 13, and thus forms an air gap 30 between the transparent member 11 and the transparent sheet electrode 12. In this configuration a change in capacitance can be eliminated even when the finger touches the transparent element 11 including a wiring region (in particular, a single wire 27). As described, the formation of an air gap 30 can prevent erroneous operation.

[0027] Furthermore, in the example of FIG. 10, a structure 31 with a centering protrusion is formed on the holding member 15, so that part of the transparent sheet electrode 12 is bent and placed on the structure 31 with the centering protrusion. As a result, the transparent sheet electrode 12 is bent to be secured to the support member 13. The transparent sheet electrode 12 can be detached when the adhesive force is reduced. However, even when the transparent sheet electrode 12 is detached, the centering protrusion structure 31 holds the transparent sheet electrode 12 since it is bent and thus maintains an air gap 30.

[0028] In addition, since the air gap 30 can be effectively formed in any position in the wiring area to prevent erroneous operation, the air gap 30 can be formed in the corresponding position depending on the peripheral design and the location of the designation. For example, an air gap 30 may be formed on a portion of the composite wire 28.

[0029] Third Embodiment

Next, an example having improved surface emission visibility in the third embodiment will be described.

11 is a sectional view of an operation display panel 6 in accordance with a third embodiment of the present invention.

As shown in FIG. 11, the light shielding walls 13a are formed to protect the light from the light source 25 next to the support member 13, and the conical surfaces 32 are formed on the light shielding walls 13a. Due to the formation of such light shielding walls 13a, a light direction region formed between adjacent light shielding walls 13a has a conical surface. As a result, the light emitted by the light source 25 is not protected and can be transmitted to the printing layer 22 of the designation of the transparent sheet electrode 12.

[0030] The conical surface 32 preferably has an angle greater than the radiation region 33 of the light source 25, but the angle can be structurally limited. The angle may not always be larger than the radiation region 33, and other angles may also improve visibility.

[0031] Furthermore, like the first embodiment, when a white or similar color element is used for the support element 13 (light protection wall 13a), the reflected light from the light source 25 can be effectively used for the printed sign layer 22, thereby improving visibility.

[0033] Fourth Embodiment

Fig is a perspective view with a spatial separation of the elements of the panel of the working display in accordance with the fourth embodiment of the present invention, and Fig is a detailed view of the connecting part of the connector in Fig.

As shown in FIGS. 12 and 13, the support member 13 has a dividing wall 34, and the electronic substrate includes a transparent sheet electrode connector 35 and a lead wire connector 36 of the main body. The connecting part 37 of the transparent sheet electrode is formed as part of the transparent sheet electrode 12 in the form of a strip, which is continuous from the composite wire 28 in Fig. 8. The connecting part 37 of the transparent sheet electrode is connected to the connector 35 of the transparent sheet electrode through an opening 13b formed in the support member 13. In addition, the lead wire 38 of the main body, which extends from the door of the refrigerator 1, is connected to the connector 36 of the lead wire of the main body. When an electric current flows into the lead wire 38 of the main body in a position in which the connecting part 37 of the transparent sheet electrode and the lead wire 38 of the main body the lead wire 38 of the main body are in close contact with each other, the induced current passes into the connecting part 37 of the transparent sheet electrode , which can cause erroneous operation of the panel 6 of the working display, when the designations of 17 operating modes do not work. To prevent this problem, the support member 13 includes a partition wall 34 to prevent tight contact between the connecting part 37 of the transparent sheet electrode and the lead wire 38 of the main body. That is, the dividing wall 34 separates the connecting part 37 of the transparent sheet electrode from the lead wire 38 of the main body, thereby protecting the connecting part 37 of the transparent sheet electrode. As a result, inadvertent operation of the operation display panel 6 can be prevented. In addition, the connecting portion 37 of the transparent sheet electrode corresponds to a “strip-shaped part on which a plurality of conductive wires are formed” in the transparent sheet electrode 12 in accordance with the present invention.

[0033] Fifth Embodiment

Fig.14 is a perspective view with a spatial separation of the elements of the panel of the working display in accordance with the fifth embodiment of the present invention and depicts all the elements of the panel of the working display, and Fig.5 is a front view of the refrigerator on which the panel of the working display in Fig.14. In FIGS. 14 and 15, the elements denoted by the same positions as the elements in FIGS. 3 and 1 refer to the same or corresponding elements.

The operation display panel 6 consists of approximately six elements, which are a transparent element 11, a transparent sheet electrode 12, a light guide 41, an outer casing 42, an electronic substrate 14 and a holding element 15. In a fifth embodiment, the light guide 41 and the outer casing 42 serve to perform a function supporting element 13 in figure 3. The light guide 41 directs the light from the light source 25 to the transparent sheet electrode 12, and the outer casing 42 supports the light guide 41.

[0034] The operation display panel 6 has the aforementioned configuration, and thus, the transparent sheet electrode 12 and the electronic substrate 14 can be connected by a connector after fixing the transparent sheet electrode 12 to the outer casing 42, and then a light guide 41 can be mounted. Therefore , a transparent sheet electrode 12, mounted on the outer casing 42, is connected to the electronic substrate 14 by means of a connector, thereby increasing efficiency and increasing productivity.

[0035] List of Reference Items

1 - refrigerator, 2 - compressor, 3 - cooling device, 4 - discharge fan, 5 - flow channel, 6 - work display panel, 11 - transparent element, 12 - transparent sheet electrode, 13 - supporting element, 13a - light-protective wall, 13b - hole, 14 - electronic substrate, 15 - holding element, 16 power button, 17 - designation of the operating mode, 18 - transparent base material, 19 - hard wiring layer, 20 - transparent conductive paint layer, 21 - insulating paint layer, 22 - printed layer (light-protective layer) 22 designations, 23 - light-diffusing furnace layer, 24 - adhesive printing layer, 25 - light source, 26 - double wall, 27 - single wire, 28 - composite wire, 29 - other rigid wiring group, 30 - air gap, 31 - design with a centering protrusion, 32 - conical surface, 33 — radiation region, 34 — dividing wall, 35 — transparent sheet electrode connector, 36 — main body lead wire connector, 37 — transparent sheet metal connector, 38 — main body lead, 41 — light guide, 42 — outer casing, 100 - refrigeration department niye, 200 - switch compartment, 300 - ice compartment, 400 - freezer compartment, 500 - vegetable compartment, 201 - camera to accommodate the switch compartment, 301 - camera to accommodate the ice machine compartment, 401 - camera to place the freezer compartment, 501 - camera to accommodate the vegetable compartment.

Claims (24)

1. The refrigerator (1) containing a working display (6), moreover, the working display includes transparent plate element (11), a multilayer sheet (12) located on the rear side of the transparent plate element and configured to determine at least a change in capacity, and an electronic substrate (14) located on the side of the multilayer sheet opposite the transparent plate element, wherein the electronic substrate includes a plurality of light sources (25) configured to emit light onto the multilayer sheet, and includes a controller configured to receive a signal defined by a multilayer sheet as a working signal and controlling a plurality of light sources for emitting light, moreover, the multilayer sheet includes transparent base material (18), many transparent conductive elements (20) located on the surface of the transparent base material facing the transparent plate element and configured to detect changes in capacitance, a light-protective layer (22) located on the surface of the transparent base material, on the side of the electronic substrate, which includes a pattern configured to display the shape of at least one of the signs and symbols, and a light-scattering layer (23) located on the surface of the light-protective layer, on the side of the electronic substrate, and configured to diffuse light emitted from multiple light sources, wherein the light-protective layer, the light-scattering layer and the plurality of transparent conductive elements are printed on the same transparent base material. 2. The refrigerator according to claim 1, further comprising a shielding wall (13a) located between the plurality of light sources. 3. The refrigerator according to claim 1 or 2, in which the multilayer sheet further includes a plurality of conductive wires (19) configured to transmit a signal defined by a plurality of transparent conductive elements to an electronic substrate, and many conductive wires are parallel to each other. 4. The refrigerator according to claim 3, in which the gap (30) is formed between the transparent plate element and the area on which there are many conductive wires of the multilayer sheet. 5. The refrigerator according to claim 2, in which the screening wall (13a) has a white surface. 6. Refrigerator according to claim 2, in which the shielding wall (13a) is inclined to increase the opening extending from at least one of the plurality of light sources to the transparent plate element. 7. The refrigerator according to claim 6, further comprising a support element (13) located between the multilayer sheet and the electronic substrate and configured to support the multilayer sheet, a shielding wall (13a) is formed on the support member. 8. The refrigerator according to claim 7, in which the multilayer sheet includes a strip-shaped part (37) on which a plurality of conductive wires are formed to be connected to the electronic substrate, and the support element includes a separation wall (34) located on the connecting portion between the strip-shaped part and the electronic substrate to protect the strip-shaped part. 9. The refrigerator according to claim 7 or 8, in which the support element includes a light guide element (41), configured to direct light from multiple light sources to the multilayer sheet, and an outer casing (42) configured to support the light guide element.

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