JP2019095816A - Camera device for storage house and storage house including the same - Google Patents

Abstract

To provide a camera device for a storage house capable of properly imaging an imaging target (stored item) as a target, and a storage house including the camera device.SOLUTION: A camera device for a storage house according to an embodiment is a device for imaging the inside of the storage house while the storage house is provided with a plate member, and includes imaging means. The imaging means images the inside of the storage house through the plate member.SELECTED DRAWING: Figure 11

Description

  Embodiments of the present invention relate to a storage camera device and a storage provided with the same.

  2. Description of the Related Art Conventionally, there is known one that can acquire information such as food in a refrigerator even from a remote place by providing a camera device inside a storage such as a refrigerator, for example (see, for example, Patent Document 1).

JP 2012-226748 A

At this time, there is a demand for properly imaging the target imaging target (stored material).
Then, the camera apparatus for storages which can image the imaging object (stored article) used as a target appropriately, and the storage provided with this are provided.

  The camera apparatus for storage according to the embodiment is for imaging the inside of the storage, and the storage is provided with a plate member and is provided with an imaging means, and the imaging means is the inside of the storage through the plate member. Capture the image.

The figure which shows typically the indoor imaging system using the camera apparatus of 1st Embodiment. A perspective view showing the appearance of a camera device Exploded perspective view of the camera device Longitudinal side view of camera device Front view of the camera device Rear view of the camera device Perspective view of the front part of the main body case Longitudinal section of slide switch part Perspective view of auxiliary board Block diagram showing the electrical configuration of the refrigerator and the camera device The perspective view in the state where the partial door of the refrigerator was opened Side view of a cross section of a refrigerator compartment Longitudinal front view with arrangement of camera device Cutaway side view of the vegetable room The figure which shows the luminous characteristic of the indoor lamp and the light reception characteristic of the illuminance sensor Flowchart showing control contents of refrigerator Flow chart showing control contents of camera device Cross-sectional view of one surface portion of a case showing a second embodiment The fracture side view of the vegetable compartment part which shows a 3rd embodiment Front view of vegetable container Longitudinal front view showing arrangement state of camera device showing fourth embodiment 11 equivalent figure which shows 5th Embodiment

  Hereinafter, the first embodiment will be described with reference to FIGS. 1 to 17.

  As shown in FIG. 1, the camera device 2 (camera device for storage) of the embodiment is disposed inside a refrigerator (food storage) 1 as a home appliance in the indoor imaging system 100.

  First, the indoor imaging system 100 will be described. The indoor imaging system 100 includes the camera device 2 for imaging the inside of the refrigerator 1, an access point 3 for communicating with the refrigerator 1 side, an operation terminal 4 and the like. Among them, the access point 3 is connected to an external network (a wide area communication network or a mobile telephone network) 5, and between the remote control terminal 4 or server 6 and the refrigerator 1 via the external network 5. It is connected communicably. In this embodiment, near field communication, for example, Bluetooth (registered trademark), between the refrigerator 1 and the access point 3, between the access point 3 and the operation terminal 4, and between the camera device 2 and the access point 3 is performed. Communication is performed by wireless communication.

  The operation terminal 4 is for inputting an imaging instruction for imaging the inside of the room to the camera device 2, and assumes a tablet type personal computer or a so-called smart phone (high-performance mobile phone). When the operation terminal 4 is located in the house 7, the operation terminal 4 is communicably connected to the access point 3 by the short distance wireless system. When the operation terminal 4 is located outside the house 7, the operation terminal 4 is communicably connected to the access point 3 via the external network 5 by wide area communication. Moreover, the operation terminal 4 can be connected to the access point 3 via the external network 5 by wide area communication even from within the house 7, and in the house 7 without passing through the access point 3. It can also communicate directly with the refrigerator 1 side.

  The server 6 is configured by a well-known computer system, and stores information (for example, an IP address and the like) for accessing the refrigerator 1 and the like, and in the present embodiment, imaging data captured by the camera device 2 Remember. In addition, although only the refrigerator 1 is shown in figure in FIG. 1, other household appliances, such as an air-conditioner not shown, are also networked.

By networking home appliances in this way, the power consumption of each home appliance can be visually provided to the user in a visible manner, and the peak of reducing power consumption in a time zone where the power demand for summer daytime etc. becomes large We provide systems for providing ease of use, comfort, or convenience, such as shift control, peak-cut power control to avoid momentary use of power that exceeds general household ratings, fault diagnosis for home appliances, etc. It becomes possible. In addition, by installing the camera device 2 in, for example, a cold storage room, it is also possible to check the indoor situation (the storage state of articles, etc.) of the refrigerator 1 or the like. Then, by storing the various information, the imaging data, and the like in the server 6, it is possible to refer to the information by the operation terminal 4 or the like via the external network 5 even in a remote place.
Next, the camera device 2 will be described.

  The camera device 2 has a case 200 as an outer shell, as shown in FIGS. The case 200 has a rectangular box-like main body case (first case part) 201 having an open surface, and a shallow rectangular box-like cover case (second case part) 202 having an open surface. The main body case portion 201 and the lid case portion 202 are made of synthetic resin (made of nonmetal). The case 200 is configured by joining the opening of the main body case 201 and the opening of the lid case 202 with a screw 200a, and forms a rectangular parallelepiped as a whole. A packing groove 201a is formed on the end face of the opening of the main body case portion 201, and a frame-like packing 203 as a waterproof member is fitted in the packing groove 201a. The main body case portion 201 and the lid case portion 202 are watertightly joined by the packing 203. The packing 203 is made of silicone rubber.

  In the main body case portion 201, a surface portion on the opposite side to the opening (a surface portion as the front as the camera device 2 and the left in FIGS. 3 and 4) corresponds to the one surface portion (imaging direction surface portion) 201I. The one surface portion 201I is flat, and a circular imaging window portion 201b is formed at the center of the one surface portion 201I. Furthermore, the imaging light window portions 201c and 201c are formed at equal distances above and below with reference to the imaging window portion 201b. Furthermore, an illumination sensor window 201d is formed in the one surface portion 201I.

The imaging window portion 201b spreads in a tapered shape in which the outside is large in diameter, and the imaging range of the imaging unit 211 described later does not image the imaging window portion 201b even when using a wide-angle lens as a lens It has become.
As shown in FIG. 7, in the one surface portion 201I, the peripheral portion of the one surface portion 201I and the peripheral portion of the imaging window portion 201b slightly protrude at the same height.

  A sheet-like cover member 204 covering the one surface portion 201I is attached and attached with a double-sided tape (not shown). However, the cover member 204 is formed with a hole 204a for not covering the imaging window portion 201b, that is, the cover member 204 corresponds to the imaging window portion at a portion facing the imaging window portion 201b. It is non-porous except for the formation of a hole 204a that exposes 201b to the outside. Thus, the imaging window 201b is not covered. The cover member 204 is made of a transparent material, and in the cover member 204, design printing (not shown) is performed in advance on the surface to be bonded. This design print is not formed on the imaging light window portions 201c and 201c and the illuminance sensor window portion 201d, and transparent portions 204b, 204b and 204c are formed.

  Further, on the upper surface portion 201J of the main body case portion 201, switch holes 201e and 201e are formed. The sheet-like switch cover 205 is adhered to the upper surface portion 201J with, for example, a double-sided tape (not shown). The switch holes 201 e and 201 e are closed by the switch cover 205. Design printings 205a and 205b are applied in advance to the side of the switch cover 205 to be adhered. However, portions of the design print 205a and 205b correspond to the switch holes 201e and 201e, and the double-sided tape is not adhered to this portion. The switch cover 205 is flexible and deformable for switch operation at the design print 205a and 205b.

  In addition, as shown in FIG. 8, a shallow-bottom, vertically-long operation element corresponding to the reed switch 206 c located in the vicinity of the inner surface of the right wall portion 201 M, which will be described later. A recess 201 f is formed. A slide cover 201g that forms a space for arranging an operator is attached to the operator recess 201f by engagement. An elongated hole 201 h is formed in the slide cover 201 g. In this case, the operator 206a is slidably disposed in the vertical direction in the space between the operator recess 201f and the slide cover 201g. A magnet 206b is provided on the operation element 206a. In addition, a knob 206d protruding from the operation element 206a is located in the long hole 201h. A slide switch 206 is configured by the operation element 206a, the magnet 206b, and a reed switch 206c described later. The slide switch 206 corresponds to a power switch for turning on and off the power. In the slide switch 206, the reed switch 206c is turned on by operating the operating element 206a downward. That is, the slide switch 206 is switched on and the power is turned on. The letter "ON" is attached to the lower part of the slide cover 201g, and the letter "OFF" is attached to the upper part.

  On the other hand, at the lower part of the lid case portion 202, a battery accommodating portion 207 is formed to project toward the main body case portion 201. The battery storage portion 207 has an opening portion 207a for taking out and taking out a battery at one end portion (rear end portion). The battery 208 is inserted from the opening 207a. The battery 208 is a lithium battery and is a primary battery. The opening 207 a of the battery housing portion 207 is closed by a battery lid (lid) 209 so as to be openable and closable. The lower edge of the battery lid 209 is engaged with the lower portion of the outer opening, and the upper portion is screwed to the upper portion of the edge of the opening 207a by a screw 209a.

The battery 208 is a power supply of the camera device 2. Therefore, the camera device 2 does not need a power cable or the like, and can be installed at an arbitrary place in the refrigerator 1.
Further, a packing 210 made of silicone rubber as a waterproof means is interposed between the opening 207 a of the battery housing portion 207 and the battery lid 209.

  Inside the case 200, an imaging unit 211 as an imaging unit, a substrate 212, and a communication module 213 as a communication unit are accommodated and disposed above the battery 208.

  The imaging unit 211 includes a lens holder 211a as an outer shell, an outer lens 211b as a lens, a lens assembly 211c, an imaging element 211d, and an imaging substrate 211e. The outer lens 211 b and the lens assembly 211 c are configured to include a wide angle lens. The wide-angle lens has a viewing angle of about 120 degrees. In the case of a general web camera as a comparative example, the viewing angle is approximately 55 degrees.

The lens holder 211a has a circular outer shape, and the outer lens 211b and the lens assembly 211c are held by the lens holder 211a. The imaging element 211d is formed of a CCD or a CMOS, and is mounted on the imaging substrate 211e. The imaging substrate 211e is attached to the rear end (the end on the right side in FIG. 4) of the lens holder 211a.
The lens holder 211a is fitted in the imaging window 201b. An O-ring 211 f as a waterproof means is interposed in this fitting portion.

  The outermost surface of the imaging unit 211 (the outermost surface of the outer lens 211b) is recessed from the outermost surface of the one surface portion 201I of the case 200 (the outer surface of the peripheral portion of the imaging window portion 201b) as shown in FIG. .

  Further, a connection terminal 211h for connecting one end of the flexible cable 211g is mounted on the imaging substrate 211e. The flexible cable 211g connects the imaging substrate 211e to a main substrate 212A described later.

  The substrate 212 includes a main substrate 212A and an auxiliary substrate 212B. In the auxiliary substrate 212B, a hole 212Ba for escaping the imaging unit 211 is formed. The auxiliary substrate 212B is attached to the back of the one surface 201I of the case 200 via a rib so as to be separated from the inner surface of the one surface 201I. In this case, the imaging substrate 211e and the flexible cable 211g are located rearward of the auxiliary substrate 212B.

  Battery connection terminals 212Bb and 212Bb are provided at the lower part of the rear surface of the auxiliary substrate 212B, and the positive terminal and the negative terminal of the battery 208 are connected to the battery connection terminals 212Bb and 212Bb.

  As shown in FIGS. 4 and 9, on the front surface portion of the auxiliary substrate 212B, the imaging lights 214 and 214 corresponding to the imaging illumination means are mounted, and the illuminance sensor 215 is mounted. The imaging lights 214, 214 face or fit into the imaging light window portions 201c, 201c in the attached state of the auxiliary substrate 212B. Further, the illumination sensor 215 faces the illumination sensor window 201d.

  Further, a reed switch 206c is mounted on the end of the rear surface of the auxiliary substrate 212B, and as shown in FIG. 8, the reed switch 206c is located near the inner surface of the right wall 201M as one wall. A configuration in which the reed switch 206c and the operating element 206a are separated by the wall of the operating element recessed portion 201f of the right wall portion 201M is used as a waterproof means.

  Furthermore, a metallic circuit pattern (not shown) for electrically connecting a plurality of electronic components is formed on the main substrate 212A and the auxiliary substrate 212B. Further, on the front surface of the auxiliary substrate 212B, as shown in FIG. 9, a ground pattern 212Bc which is a circuit pattern made of metal is formed on almost the entire surface. The ground pattern 212Bc acts as an electrical shield for shielding noise from the outside of the case 200.

  Further, a connection terminal 212Be for connecting the flexible cable 212Bd is mounted on the auxiliary substrate 212B. The flexible cable 212Bd connects the auxiliary substrate 212B and the main substrate 212A.

  The main substrate 212A is positioned at the rear of the auxiliary substrate 212B and attached to the main case portion 201 by screwing. On the main board 212A, a microcomputer as a camera side control unit 220 (described later) for mainly controlling the camera device 2 is mounted. Further, on the upper portion of the main board 212A, a setting switch 216 for setting start, setting confirmation or setting end, and a mode switch 217 for specifying or selecting various modes are mounted as switches. The setting switch 216 and the mode switch 217 are composed of a tact switch (push switch), and have operation elements 216a and 217a, respectively. The switches 216 and 217 are switched by pressing the operation members 216a and 217a from the top to the bottom, and return to the original state after the operation. Furthermore, as shown in FIG. 4, the operators 216 a and 217 a are disposed in the switch holes 201 e and 201 e, and when the design print 205 a and 205 b of the switch cover 205 is pressed, The portions are flexibly deformed and the operation members 216a and 217a are pressed. The portions of the design print 205a and 205b function as the setting switch 216 and the operation units 216b and 217b of the mode switch 217 (the setting switch 216 and part of the mode switch 217 are configured).

  Further, an acceleration sensor 218 and a temperature sensor 219 (see FIG. 10) are mounted on the main substrate 212A. The acceleration sensor 218 detects the installation posture of the camera device 2 (longitudinal, horizontal, downward of the one surface portion 201I, upward of the one surface portion 201I).

  The temperature sensor 219 detects the temperature of the place where the camera device 2 is installed. In the camera device 2, when the temperature detected by the temperature sensor 219 is in the cold storage temperature zone, it is determined that the camera device 2 is installed in the cold storage room, and when the detected temperature is the freezer temperature range, the camera is It is determined that the device 2 has been installed. In this case, if it is determined that the refrigerator is installed in the freezer compartment, there is a possibility that a failure or the like may occur, so that fact is transmitted to the refrigerator 1 and notified to the user by the operation panel 22 of the refrigerator 1 or the like.

  Furthermore, a connection terminal 212Ab for connecting the flexible cable 212Aa is mounted on the main substrate 212A. The flexible cable 212Aa connects the main substrate 212A and the communication module 213.

  The communication module 213 is attached to the inside of the case 200 by screwing to the main body case portion 201 at a position behind the substrate 212. The communication module 213 is configured by including a module substrate 213b on which a circuit for communication control is mounted inside a module case 213a. Further, an antenna 213c is formed on the module substrate 213b by a pattern. The antenna 213c is provided on the side of the other surface portion 202T which is a surface portion opposite to the one surface portion 201I in the case 200.

  The communication module 213 transmits imaging data in the storage unit imaged by the imaging unit 211 to the operation terminal 4 or the server 6 via the access point 3. The reason for transmitting to the server 6 is to make the server 6 store the imaging data. Here, the imaging data is data including an image in the room, for example, data of a well-known format such as a bitmap format, JPEG format, or MPEG format (still image, moving image), compression or encryption of the data, or image The data converted by processing, etc. may be in any format as long as the data in the state of the refrigerator 1 can be confirmed by the operation terminal 4 or the like.

  In the camera device 2, the imaging unit 211, the substrate 212, the communication module 213, and the battery 208 are configured as a unit (integral body) 2 </ b> A by a case 200. The battery 208 is provided at a position not covering the communication module 213. That is, the communication module 213 is provided at a position not covering the favorable transmission / reception direction (the direction of the arrow A) of the antenna 213c.

  The distance H1 (see FIG. 4) between the antenna 213c of the communication module 213 and the substrate 212 is set to, for example, 10 mm or less of the wavelength of the radio wave. In this case, assuming that the frequency of the radio wave is 2.5 GHz, the wavelength is about 120 mm, and the dimension is set to 1/2 (60 mm) or less of the wavelength.

  Here, in the camera device 2, as shown in FIG. 4, since the battery 208 having a large mass is located at the lower part of the case 200, the center of gravity G of the camera device 2 with respect to the center (volume center) C of the case 200. There are different positions, in this case below.

  Further, on the outer surface of the upper surface portion 201J which is the outer surface opposite to the battery 208 in the case 200, operation portions 216b and 217b (preventing means) which are a part of the setting switch 216 and the mode switch 217 exist.

  The electrical configuration of the camera device 2 will be described with reference to FIG. The camera side control unit 220 is configured by the microcomputer described above which the main substrate 212A has. The camera side control unit 220 includes a CPU 220a, a ROM 220b, a RAM 220c, a clock unit 220d, a non-volatile memory 220e as information storage means, and the like, and controls the entire camera device 2. Specifically, the camera side control unit 220 controls the imaging timing by the imaging unit 211, controls to adjust the imaging environment at the time of imaging (lighting control of the imaging light 214), transmits imaging data by the communication module 213, and an illuminance sensor Control or the like for receiving (accepting) an imaging instruction to be described later according to the processing 215 or the like is performed. Further, in the present embodiment, the camera side control unit 220 also performs image processing for correcting the captured image.

  The clock unit 220d is configured of a real time clock module, has a time and calendar function, and can measure real time (time, date, day of the week).

  The illuminance sensor 215 connected to the camera-side control unit 220 is a so-called illuminance sensor, and detects the illuminance around the camera device 2. More specifically, the illuminance sensor 215 detects light energy of a predetermined wavelength band (in the present embodiment, light energy emitted from indoor illumination lamps 130 and 132 described later). The light energy detected by the illuminance sensor 215 is converted into an electrical signal and output to the camera side control unit 220.

  In the case of the present embodiment, the final signal form of the imaging instruction from the user is configured as indicated by the light energy (the blinking of the predetermined pattern of the indoor illumination lamps 130 and 132 described later) emitted in the predetermined pattern. When the illumination sensor 215 detects the blinking of the predetermined pattern, the camera-side control unit 220 determines that it is an imaging instruction.

  The camera device 2 having such a configuration is used when the slide switch 206 is turned on (power on state), and is always in the low power mode (sleep control mode) which consumes relatively less power than the normal operation mode. When the imaging instruction is received, the normal operation mode is restored to image the inside of the refrigerator.

  On the other hand, as shown in FIG. 11, the refrigerator 1 in which the camera device 2 is installed is, in order from the upper part of the main body 102, a refrigerator compartment 103, a vegetable compartment 104, an icemaker 105, an upper part. A freezer compartment 106 and a lower freezer compartment 107 are provided. The cold storage room 103 and the vegetable room 104, and the ice making room 105 and the upper freezing room 106 are partitioned by a heat insulating partition wall (not shown). The refrigerator compartment 103 is opened and closed by so-called double-opening (rotary) left and right doors 103a and 103b rotatably supported by the hinges 102a and 102b.

  The vegetable compartment 104, the icemaker 105, the upper freezer compartment 106 and the lower freezer compartment 107 are opened and closed by a drawer type door 104a, a door 105a, a door 106a and a door 107a, respectively. In this case, the length of the right door 103b (the length from the rotation center of the hinge 102b to the open end) is formed longer than the length of the left door 103a.

  Each door is provided with a door sensor 124 (see FIG. 10) for detecting the open / close state thereof. In addition, the structure of the refrigerator 1 shown in FIG. 11 is an example, and the arrangement | positioning order of each storage may differ, for example, the structure which the upper freezer compartment 106 is a switching chamber which can switch refrigeration and refrigeration may be sufficient.

  In the left door 103a of the refrigerator compartment 103, a door pocket 108a, a door pocket 109a and a door pocket 110a are provided in order from the top, and in the right door 103b, a door pocket 108b, a door pocket 109b, a door pocket 110b in order from the top Is provided. In addition, in the refrigerator compartment 103, a plurality of shelf boards 111a to 111d (corresponding to plate members) formed of a transparent material such as glass, for example, are provided. A special purpose room 112, such as a chilled room, is arranged. Further, inside the cold storage room 103, indoor illumination lights 130, 132 (see FIG. 10) as illumination means are provided. The indoor lamp 130 is provided on the ceiling, and the indoor lamp 132 is provided on the side surface, which is not shown in FIG. Among them, the indoor illumination light 130 is provided on the upper side of the interior of the storage, and the indoor illumination light 132 is provided to illuminate a specific position in the interior of the storage such as a central portion or lower portion of the interior.

  The left door 103a and the right door 103b of the refrigerator compartment 103 have different sizes, but have substantially the same material. The configuration will be described on behalf of the right door 103b. The right door 103b is composed of a glass plate 103b1 whose front surface is formed of an insulating glass material, and its rear surface (inner surface) is composed of an inner plate 114 and a vertical plate 115 (see FIG. 11) made of nonmetallic resin. There is. And the urethane which is a heat insulating material is filled with the inside as the filler.

In the vegetable compartment 104, as shown in FIG. 14, two upper and lower vegetable containers 104b and 104c are provided. The upper vegetable container 104b is made of a transparent material (such as synthetic resin). The lower vegetable container 104c may also be made of a transparent material.
Here, the shelf plates 111a to 111d are almost horizontal and parallel to each other.

As shown in FIGS. 11 and 12, the camera device 2 is disposed, for example, on the top surface of the uppermost shelf plate 111a in a position determined by the positioning member 180. In this case, the upper surface of the shelf plate 111a is the placement surface, and the one surface portion 201I is the placement surface. In this case, the imaging range of the imaging unit 211 is a case where the plate members are the shelf plates 111a to 111d in a substantially horizontal state as in the present embodiment, and one surface portion of the case 200 at the center of the upper surface of the uppermost shelf plate 111a. It is an imaging range in which the left and right ends or the front and rear ends of the bottom surface of the inside of the refrigerator (in this case, the refrigerator compartment 103) enter when the 201I is disposed downward.
In the arrangement state of the camera device 2, as can be seen from FIG. 13, the lens (outer lens 211b) does not contact the shelf plate 111a.

  The refrigerator 1 has a storage side control unit 121 shown in FIG. The storage-side control unit 121 is configured by a microcomputer having a CPU 121a, a ROM 121b, a RAM 121c, a timer 121d, and the like, and controls the entire refrigerator 1. Specifically, the storage-side control unit 121 is, for example, the temperature in the storage detected by the temperature sensor 123 or the opening / closing state of the door detected by the door sensor 124 so that the operation state set from the operation panel 122 is obtained. Based on the operation state of the refrigeration mechanism 125 for refrigeration and the refrigeration mechanism 126 for refrigeration that constitute a known refrigeration cycle are controlled.

  The operation panel 122 is provided with a panel display 127, a panel LED 128, and a panel buzzer 129. The panel display 127 displays setting values and the like. The panel LED 128 is provided to light an operation switch, an operation state, and the like. The panel buzzer 129 is configured of a piezoelectric buzzer or the like, and notifies the content of the operation by emitting a sound (sound energy) according to the operation.

The indoor illumination lights 130 and 132 are composed of LEDs and light up when the door is opened. The indoor illumination lights 130 and 132 also serve as a signal output unit, and can be blinked in a predetermined pattern under the control of the storage control unit 121. The blinking of the predetermined pattern is a signal indicating an imaging command for the camera device 2. An imaging command by the blinking of the predetermined pattern is received (received) by the illuminance sensor 215. In this case, the light reception characteristic of the illuminance sensor 215 is set to be substantially the same as the LED light emission characteristic of the indoor illumination lamps 130 and 132. A region which is substantially the same among the wavelength regions λα shown in FIG. 15 is employed.
The blower 131 is provided to circulate cold air in the refrigerator 1 in a normal operation.

  The communication adapter 134 communicates with the access point 3 and the operation terminal 4 in the room, and in the present embodiment, the communication adapter 134 is detachably provided to the refrigerator 1. In addition, although only the refrigerator 1 is illustrated in FIG. 1, the communication adapter 134 is provided also in other household appliances, such as an air conditioner, and makes household appliances network. The communication adapter 134 is also configured to be able to directly communicate with the camera device 2 without the access point 3. Since this communication adapter 134 is also used for visualizing as described above, it basically operates at all times when the refrigerator 1 is in operation.

  Here, when the operation terminal 4 is operated by the user at a remote place and outputs an imaging command, the imaging command is transmitted to the refrigerator 1 via the external network 5 and the access point 3.

In the refrigerator 1 that has received this imaging command, it is determined in step R1 shown in FIG. 16 that the imaging command has been received. Then, the indoor illumination lamps 130 and 132 are caused to blink in a predetermined pattern to transmit an imaging command in the form of an optical signal to the camera device 2 (step R2).
The operation of the camera device 2 will be described.

  When the slide switch 206 of the camera device 2 is turned on, the power is turned on, and the camera control unit 220 performs control of FIG. First, initialization is performed by the user (step S1). In this initial setting, the camera focus setting and the automatic imaging timing (for example, the imaging time and the like every day) are set. Thereafter, the process shifts to sleep control (step S2, sleep control means). In this sleep control state, functions other than the function of receiving an imaging command from the indoor illumination light 130 or 132 and the function of determining whether the time measured by the clock unit 220 d has reached the set imaging timing It is stopped. Therefore, the battery consumption of the battery 208 which is a power supply is suppressed. In this case, the operation of the communication module 213 is also stopped. The reason for this is that the continuation of the operation of the communication module 213 makes the consumption speed of the battery 208 faster. On the other hand, in the function of receiving an imaging command from the indoor lamp 130 or 132 described above, the consumption speed of the battery 208 is low, and the consumption can be further suppressed.

In this sleep control state, if an imaging command is received from the indoor lamp 130 or 132 (step S3), or if the time measured by the clock unit 220d is the set imaging timing (step S4), the normal operation is performed. The operation mode is restored (step S5). Then, the room is imaged (step S6), and the imaging data is transmitted (step S7).
In this case, the imaging data is transmitted to the server 6 and stored, and is transmitted from the server 6 to the operation terminal 4.

  In the present embodiment described above, as shown in FIG. 13, the camera device 2 includes the case 200 and the imaging unit 211 as an imaging unit provided in the case 200, and the one surface portion 201I of the case 200 The inside of the refrigerator compartment 103 (inside the storage) is imaged by the imaging unit 211 from the provided imaging window unit 201b. And this camera apparatus 2 arrange | positioned the case 200 in the shelf 111a as a plate member for the storage arrangement | positioning which the refrigerator 1 equipped with the attitude | position in which the one surface part 201I turned to the inside of the refrigerator compartment 103. FIG.

  The shelf boards 111 a to 111 d are arranged almost horizontally since they are for arranging a storage item, and are also suitable for arranging the case 200 of the camera device 2. In particular, when the one surface 201I of the case 200 (the surface facing the imaging direction with the outer lens 211b) is disposed downward on the top surface of the shelf plate 111a, the inside of the storage is widely included in the imaging range. Therefore, according to the present embodiment, the imaging direction can be set to an appropriate direction by using the shelf board 111a. In this case, since the shelf board 111a is a transparent member, the lower part of the shelf board 111a can be imaged without any problem. If the shelf board 111 a is opaque, a hole for imaging may be formed in a portion corresponding to the imaging unit 211.

  In the present embodiment, the imaging unit 211 includes the outer lens 211b and the lens assembly 211c as lenses, and the outer lens 211b is disposed in the imaging window portion 201b, and the outer lens 211b is the shelf plate 111a. It did not touch. According to this, it is possible to prevent the outer lens 211b from being soiled or damaged.

  Further, according to the present embodiment, since the outer lens 211b is provided at a position recessed from the one surface portion 201I of the case 200, it is possible to prevent the outer lens 211b from being soiled or damaged. Furthermore, since the outer lens 211b does not protrude, it is possible to make the one surface portion 201I a flat surface. Therefore, this one surface portion 201I can be disposed on the disposition surface as it is.

  In the present embodiment, the lens composed of the outer lens 211b and the lens assembly 211c is configured by a wide angle lens, and the imaging range of the imaging unit 211 is not imaged and the peripheral portion of the imaging window 201b is not imaged using this wide angle lens It was an imaging range. According to this embodiment, the entire wide imaging range of the wide-angle lens can be used for in-chamber imaging.

  Further, in the present embodiment, the lens is configured of a wide-angle lens, and the imaging range of the imaging unit 211 is the uppermost shelf plate in the case where the plate members are the plurality of shelf plates 111a to 111d in a substantially horizontal state. In a state where the one surface portion 201I of the case 200 is disposed downward at the center of the upper surface of the surface 111a, the imaging range is such that the left and right ends or the front and rear ends of the bottom surface in the storage are included. According to this embodiment, the inside of the storage can be imaged in a sufficiently wide range.

  According to the present embodiment, since the shelf board 111a is made of a transparent material, even if the one surface portion 201I of the case 200 is disposed on the upper surface of the shelf board 111a, the lower part of the shelf board 111a can be imaged without any problem.

  Further, in the present embodiment, the illuminance sensor 215 is provided on the one surface portion 201I of the case 200. According to this embodiment, when the plate member is transparent, it is possible to detect the light in the storage (the blinking of the predetermined pattern of the indoor illumination lamps 130 and 132) even if the one surface portion 201I is disposed. In addition, since the one surface 201I, which is the side to which the lens is directed, is the side that receives the light (flickering of a predetermined pattern) from the indoor illumination lights 130 and 132, the illumination sensor 215 is provided on the one surface 201I. It is easy to receive the light from the lights 130 and 132.

  Further, according to the present embodiment, since the case 200 is a rectangular parallelepiped, any surface portion can be a placement surface, and for example, the one surface portion 201I can be disposed upward or sideways.

  Further, according to the present embodiment, since the imaging window portion 201b is formed at the center of the one surface portion 201I of the case 200, for example, when rearranging the camera device 2 in FIG. 12 and FIG. Even if 200 is turned 180 degrees in the horizontal direction and rearranged, the same imaging range as the previous one can be imaged.

  Further, according to the present embodiment, since the imaging light 214 as the imaging illumination means for illuminating the inside of the chamber is provided on the one surface portion 201I of the case 200, it is possible to favorably image the inside of the dark chamber when the door is closed. Become. In this case, according to the present embodiment, since a plurality of imaging lights 214 are provided and provided around the imaging window portion 201b, light can be widely applied to the field of view to be imaged by the imaging unit 211.

  Further, according to the present embodiment, since the plurality of imaging lights 214 are positioned at the region sandwiching the imaging window portion 201b, light can be applied to both sides of the center of the imaging direction, and the imaging range is vertically long, When it is horizontal, it becomes possible to light the whole.

  Further, in this case, according to the present embodiment, since the imaging light 214 is positioned at an equal distance from the imaging window portion 201b, the imaging range of the imaging unit 211 can be illuminated uniformly.

  Further, according to the present embodiment, the illuminance sensor 215 is provided on the one surface portion 201I of the case 200, and the light receiving characteristic of the illuminance sensor 215 is substantially the same as the light emitting characteristic of the indoor illumination lamps 130 and 132 which are illumination means provided in the storage. And According to this, the light reception sensitivity of the illuminance sensor 215 is improved, and the imaging command (the blinking of the predetermined pattern) from the indoor illumination lights 130 and 132 can be reliably received.

  A protrusion may be provided on the one surface portion 201I of the case 200 so as to protrude to the outside of the case 200 from the lens (outside lens 211b). In this way, the lens does not contact the shelf 111a.

  Further, as shown in FIG. 18 shown as the second embodiment, a sheet 230 made of a transparent member may be provided on the imaging direction side of the outer lens 211 b. In this way, it is possible to prevent the outer lens 211b from being scratched and to achieve waterproof.

  Further, it may be as shown in FIGS. 19 and 20 shown as the third embodiment. That is, as a plate member, in addition to the shelf, there are upper and lower vegetable containers 104b and 104c, which are upper and lower two-tiered storage containers. In this case, one surface portion 201I of the case 200 may be disposed on the upper surface of the bottom portion of the upper vegetable container 104b. Furthermore, in this case, the imaging range of the imaging unit 211 is the left or right end or the front or rear end of the bottom surface of the lower vegetable container 104c in a state where the one surface 201I of the case 200 is disposed downward at the bottom center of the upper vegetable container 104b. It is considered as an imaging range in which the department enters.

  According to this embodiment, the upper vegetable container 104b can be used to dispose the case 200 in a proper orientation (a direction for imaging the lower vegetable container 104c). In addition, the imaging range is also an appropriate range.

  In addition, an operation portion of the switch may be provided on the one surface portion 201I of the case 200. In this case, the operation portion may be flush with or recessed from the one surface portion 201I. In this way, even if there is an operation portion of the switch on the one surface portion 201I, the one surface portion 201I can be disposed on the plate member (the one surface portion 201I can be made a placement surface).

  Further, the illumination sensor may be provided on a surface different from the one surface 201I of the case 200. In this case, when the one surface portion 201I is a placement surface, the blinking of the predetermined pattern from the indoor illumination lamps 130 and 132 can be favorably received.

  Also, it may be as shown in FIG. 21 shown as the fourth embodiment. The camera device 2 may have a configuration in which the imaging unit 211 protrudes from the imaging window unit 201b of the one surface unit 201I of the case 200. In this case, a fixture 235 may be disposed on the side of the one surface portion 201I so that the outer lens of the imaging unit 211 does not contact the shelf plate 111a (plate member).

Further, as shown in FIG. 22 shown as the fifth embodiment, one surface portion 201I of the case 200 may be disposed on the inner surface of the vertical wall of the door pocket 109b as a plate member. In this case, since the vertical wall of the door pocket 109b faces the inside of the storage, the one-surface portion 201I also faces the inside of the storage. Thus, the one surface portion 201I can be properly oriented by using the door pocket 109b.
The storage is not limited to a refrigerator, but may be a refrigerated case, a storage warehouse, or the like.
According to the present specification, the following problems can be extracted.

In the camera device, an imaging means is provided in a case, and an imaging window is provided on one surface of the case. And this camera apparatus is installed (arranged) in a storage so that it may turn to the imaging object direction which makes the said one surface part a target. When the inside of the storage is imaged by the camera device, the one surface portion with the imaging window portion is properly directed to the imaging target in the storage, and the imaging target (stored article) to be a target is properly imaged from this arrangement position There is a demand to want to do.
In addition, the embodiments include the following inventions.
The storage camera apparatus, wherein the imaging unit includes a lens, the lens is disposed in the imaging window, and the lens is not in contact with the plate member.
The storage camera apparatus, wherein the lens is provided at a position recessed from the one surface portion of the case.
The storage camera apparatus, wherein the one surface portion of the case is provided with a protrusion that protrudes toward the outside of the case from the lens.
The storage camera apparatus wherein a sheet made of a transparent member is provided on the imaging direction side of the lens.
The storage camera apparatus, wherein the lens is configured by a wide-angle lens, and an imaging range of the imaging means is an imaging range in which the peripheral portion of the imaging window is not imaged.

  The lens is composed of a wide-angle lens, and the imaging range of the imaging means is a plurality of shelf plates in which the plate member is substantially horizontal, and the one surface portion of the case faces downward to the center of the top surface of the uppermost shelf plate. The storage camera apparatus which is an imaging range in which the left and right ends or the front and rear ends of the bottom surface in the storage are included in the arranged state.

The lens is composed of a wide-angle lens, and in the imaging range of the imaging means, the plate member is a storage container of upper and lower two stages, and the one surface portion of the case is disposed downward at the center of the upper surface of the bottom of the upper storage container. The storage camera apparatus, which is an imaging range in which the left and right ends or the front and rear ends of the bottom surface of the lower storage container are included.
The storage camera apparatus, wherein the storage comprises a plate member made of a transparent material as the plate member.
An operation unit of a switch is provided on the one surface portion of the case, and the operation portion is flush with or recessed from the one surface portion.
The storage camera apparatus wherein an illumination sensor is provided on the one surface of the case.
The storage camera apparatus wherein an illumination sensor is provided on a surface different from the one surface of the case.
The storage camera apparatus wherein the case is a rectangular parallelepiped.
The storage camera device wherein the imaging window is formed at the center of the one surface of the case.
The storage camera apparatus wherein a plurality of imaging illumination means for illuminating the interior of the storage unit are provided around the imaging window on the one surface of the case.
The storage camera apparatus, wherein the plurality of imaging illumination units are located at portions sandwiching the imaging window.
The storage camera apparatus, wherein the plurality of imaging illumination units are located around the imaging window and at an equal distance from the imaging window.

  An illuminance sensor is provided on the one surface portion of the case, and the light receiving characteristic of the illuminance sensor is substantially the same as the light emitting characteristic of the illumination means provided in the storage.

  It is a camera apparatus for storages provided in an inside of a storage and provided with an image pickup means and which picturizes the inside of a storage by said image pickup means, and said image pickup means is light energy emitted with a predetermined pattern from a lighting means provided in said storage. A storage camera apparatus provided with an illuminance sensor for receiving an instruction from the light source and receiving the instruction;

  The imaging device includes a case for accommodating the imaging means, the imaging means for imaging from an imaging window portion provided in the case, and the case is provided with the illuminance sensor for receiving an imaging instruction. Camera device for storage.

The imaging means includes a lens disposed in an imaging window provided in the case, and the lens is provided at a position recessed from one surface of the case where the imaging window is provided. Storage camera device.
The storage camera apparatus, wherein the one surface portion of the case is provided with a protrusion that protrudes toward the outside of the case from the lens.
The storage camera apparatus wherein a sheet made of a transparent member is provided on the imaging direction side of the lens.
The storage camera apparatus, wherein the lens is configured by a wide-angle lens, and an imaging range of the imaging means is an imaging range in which the peripheral portion of the imaging window is not imaged.
An operation unit of a switch is provided on the one surface portion of the case, and the operation portion is flush with or recessed from the one surface portion.
The storage camera apparatus wherein the case is a rectangular parallelepiped.
The storage camera device wherein the imaging window is formed at the center of the one surface of the case.
The storage camera apparatus wherein a plurality of imaging illumination means for illuminating the interior of the storage unit are provided around the imaging window on the one surface of the case.
The storage camera apparatus, wherein the plurality of imaging illumination units are located at portions sandwiching the imaging window.
The storage camera apparatus, wherein the plurality of imaging illumination units are located around the imaging window and at an equal distance from the imaging window.
The storage camera apparatus in which the light receiving characteristic of the illuminance sensor is substantially the same as the light emission characteristic of the illumination means provided in the storage.
A storage provided with the storage camera device described above.

  While certain embodiments of the present invention have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, substitutions, and modifications can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and the gist of the invention, and are included in the invention described in the claims and the equivalent scope thereof.

  In the drawings, 1 is a refrigerator (storage), 2 is a camera device (storage camera device), 4 is an operation terminal, 6 is a server, 130, 132 is an indoor light (lighting means), 134 is a communication adapter, 100 is an indoor An imaging system 200, a case 203, a packing 203, a cover member (waterproof means) 204, a switch cover 205, a slide switch 206, a battery 208, an imaging unit 211 (imaging means), an O ring 211f, and 212 A substrate 213 is a communication module, 214 is an imaging light (illumination means for imaging), 215 is an illuminance sensor, 216 is a setting switch, 217 is a mode switch, and 220 is a camera side control unit.

Claims (4)

A storage camera device for imaging the inside of a storage, comprising:
A plate member is provided in the storage,
Equipped with imaging means,
The storage camera device for imaging the inside of the storage through the plate member.   The storage camera apparatus according to claim 1, wherein the imaging unit images the inside of the storage through the transparent portion of the plate member.   The storage camera apparatus according to claim 1, wherein the imaging unit images the inside of the storage through an opening provided in the plate member.   A storage provided with the storage camera device according to any one of claims 1 to 3.

Images