JP4488571B2 - Temperature recording device holding member - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a holding member for a temperature recording device for detecting and recording the temperature of a monitoring target such as food.
[0002]
[Prior art]
Due to recent advances in the logistics system, transport of refrigerated or frozen foods has become active, but until now no attention has been paid to temperature changes in foods being transported. . Therefore, for example, when the frozen food is thawed while being transported in a freezer car and then frozen again, it is difficult to grasp it after the fact.
[0003]
In recent years, bactericidal infection caused by cooked foods has become a problem, and temperature management of foods from cooking to packaging to refrigeration / frozenness has become important. On the other hand, as in the case of space foods, temperature and time are important for food temperature management (HACCP (Hazard Analysis Critical Control Point) system developed by NASA).
[0004]
In view of this, a temperature recording device has been proposed for detecting and recording a history of temperature changes over time during transportation or storage of food or during cooking. Since this temperature recording device uses a built-in battery as a power source and is small and capable of measuring temperature for a long period of time, it can be stored in a food container or a packaging container, after transportation of food, or By taking out the data after cooking and outputting the data, it is possible to grasp the history of the temperature change of the food.
[0005]
[Problems to be solved by the invention]
By the way, when such a temperature recording device records a temperature around the case by incorporating a temperature detection means, a recording means, a power source, etc. in a small metal case, for example, the handling of the temperature recording device is a problem. It becomes. That is, since the temperature recording device is small, there is a high risk of being lost. In addition, due to the small size, there is a problem that it is difficult to attach when recording a temperature at a fixed point.
[0006]
Furthermore, as described above, the temperature recording device itself is handled with a finger when it is stored or taken out in a food container or a packing container, so that erroneous temperature data is recorded due to body temperature. There was a problem.
[0007]
The present invention has been made in order to solve the conventional technical problem, and provides a holding member that makes it easy to handle a temperature recording apparatus and can perform temperature recording without any trouble.
[0008]
[Means for Solving the Problems]
That is, the holding member according to the first aspect of the present invention includes a main body having a mounting portion for mounting on a mounting surface, temperature detecting means for detecting the temperature of a recording target, recording side storing means for holding its own ID code, watch Means, a transmission / reception means for transmitting / receiving data to / from the outside, a recording means for recording the temperature data detected by the temperature detection means corresponding to the time, and a power supply are housed in the case, and the temperature around the case is stored. It is composed of a holder with a holding unit that holds the temperature recording device for recording, and the holder can be detachably attached to the main body without touching the temperature recording device with the holding unit holding the temperature recording device And As a whole, it has a shape that is bent into a substantially "<" shape, When removed from the main body and placed on the placement surface, the temperature recording device is kept away from the placement surface. Can be held Is.
[0009]
The holding member of the invention of claim 2 is characterized in that, in addition to the invention, the holding portion is made of a heat insulating material.
[0010]
A holding member according to a third aspect of the invention is characterized in that, in addition to the above-described inventions, the temperature recording device of the holding portion is held away from the mounting surface while being attached to the mounting surface by the mounting portion.
[0011]
According to a fourth aspect of the present invention, there is provided a holding member according to any one of the above inventions, wherein the attachment portion is formed by a screw hole.
[0012]
A holding member according to a fifth aspect of the present invention is characterized in that, in the first, second, or third aspect, the attachment portion is constituted by a magnet.
[0013]
According to a sixth aspect of the present invention, there is provided a holding member according to any one of the above inventions, wherein the holder is provided with a display unit for displaying predetermined information relating to the temperature recording device.
[0014]
According to the present invention, the temperature detection means for detecting the temperature of the recording target, the recording side storage means for holding its own ID code, the clock means, the transmission / reception means for exchanging data with the outside, and the temperature detection means Since the recording means and the power source for recording the temperature data detected in accordance with the time are stored in the case, the temperature recording device for recording the temperature around the case can be held in the holding portion of the holding member. Even if the temperature recording device is small, it can be handled easily.
[0015]
Also, The present invention According to the present invention, the holding member is composed of a main body having an attachment portion for attaching to the attachment surface and a holder having the holding portion, and the temperature recording device is held in the holding portion with the temperature recording device being held in the temperature recording device. Since the holder can be detachably attached to the main body without being touched, it is possible to avoid the disadvantage that abnormal temperature data is recorded in the temperature recording device. For example, when performing temperature recording with the temperature recording device fixed to a fixed point, the main body is attached to the mounting surface and the temperature recording device is held by the holder, and the holder is attached to the main body without touching the temperature recording device. Can be attached to or detached from the main body, and the temperature recording apparatus can be handled more easily and safely.
[0016]
In particular, the holder of the holding member As a whole, it has the shape of “ku”, When removed from the main body and placed on the placement surface, the temperature recording device is kept away from the placement surface. Can be held Therefore, even when the holder is detached from the main body and placed on the placement surface, it is possible to avoid inconvenience that the temperature recording apparatus directly affects the temperature recording device directly from the placement surface.
[0017]
According to the invention of claim 2, in addition to the above, since the holding member is made of a heat insulating material, the holding member itself is transmitted to avoid the disadvantage of adversely affecting the temperature recording apparatus. It becomes possible to reduce. As a result, by using the holding member of the present invention as a whole, accurate temperature recording by the temperature recording device can be achieved.
[0018]
Furthermore, according to the invention of claim 3, in addition to the above inventions, the temperature recording device of the holding unit is held away from the mounting surface in a state of being mounted on the mounting surface by the mounting portion. For example, when measuring temperature data with the temperature recording device fixed at a fixed point, the temperature recording device can be easily attached to the attachment surface using the attachment portion of the holding member. In particular, since the temperature recording device is held away from the mounting surface in the mounted state, inconveniences that adversely affect the temperature directly from the mounting surface to the temperature recording device can be avoided in advance. The temperature can be recorded reliably.
[0019]
According to the invention of claim 4, since the attachment portion is constituted by a screw hole in each of the above inventions, screwing and fixing to the attachment surface is facilitated, and according to the invention of claim 5, Since the attachment portion is composed of a magnet, the fixing work when the attachment surface is a magnetic body is extremely easy.
[0020]
According to the invention of claim 6, in addition to the above inventions, the holder is provided with a display portion for displaying predetermined information relating to the temperature recording device. In addition, the temperature recording device can be easily identified by displaying and setting the installation location.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the embodiment, for example, the present invention will be described taking a temperature recording system used when a low temperature article is delivered by a low temperature delivery vehicle in a convenience store chain as an example. In this case, the system is constructed from a personal computer (hereinafter simply referred to as a personal computer) 1 as a main control device and a button-type temperature memory (hereinafter referred to as a cool memory) 3 as a temperature recording device.
[0022]
1 is a perspective view of a personal computer 1 and a button reader 2 serving as a reading-side transmitting / receiving means, FIG. 2 is a functional block diagram of the personal computer 1, FIG. 3 is a perspective view of a cool memory 3, and FIG. Each figure is shown. FIG. 24 is a perspective view of the holding member 51 of the present invention in a state where the cool memory 3 is held. In FIG. 1, a personal computer 1 includes a keyboard 4 and a mouse 9 (FIG. 2) as input means and a CRT display 6 as display means in the main body.
[0023]
A signal line 17 is connected to the personal computer 1 by a connector, and the button reader 2 is connected to the signal line 17 by a coupler. The button reader 2 is formed with a plurality (four in the embodiment) of accommodating portions 11... As connecting portions for detachably inserting a cool memory 3 to be described later. The button reader 2 according to the embodiment can be equipped with three cool memories 3 at a time with one place serving as a connecting portion of the personal computer 1.
[0024]
Next, in FIG. 2, a personal computer 1 is, for example, a personal computer installed in a distribution store of a convenience store chain, and includes a CPU (microcomputer) 31 serving as main control means, a memory 32 including a RAM, and a hard disk 7 ( This may be a flash memory, etc. Also, the memory 32 and the hard disk 7 serve as reading side storage means), a bus I / O interface 34 as reading side transmission / reception means, and the like. ing. The CRT display 6, keyboard 4 and mouse 9 are connected to the I / O interface 33.
[0025]
The bus I / O interface 34 is connected to the signal line 17, and exchanges data with the button reader 2 via the signal line 17. The hard disk 7 of the personal computer 1 includes a protocol for performing data communication with the button reader 2 (actually a cool memory 3 to be described later), software for displaying the data on the CRT display 6, and alarm confirmation software. A control program such as a program and software for identifying the program is set.
[0026]
Next, the cool memory 3 attached to the button reader 2 will be described with reference to FIGS. The cool memory 3 includes a small metal case 3A having a thin cylindrical button battery shape having a step as shown in FIG. 3, and a flange 3B protruding outward is formed on the bottom surface of the case 3A. ing. The case 3A includes an interface 132 serving as a recording side transmission / reception unit, an ID unit (recording side storage unit) 133 that holds its own ID code, a memory control unit 136, memories 137 and 138, a transmitter 139, and a clock control. Unit 141 and its register 142, temperature alarm memory 143, histogram memory 144, temperature history memory 146 (the recording unit is constructed by these), battery (lithium battery) 147, measurement control unit 148 and sensor unit (temperature detection unit) 149 is built in.
[0027]
The cool memory 3 is placed in a container (recording target) containing refrigerated foods such as lunch boxes and beverages delivered to a convenience store, for example, and the temperature of the atmosphere (air around the cool memory 3) in the container is stored. It is used to detect and record the food temperature substantially. In this case, the measurement control unit 148 uses the sensor unit 149 to measure the food temperature (temperature in the container) at a predetermined sampling period (measurement interval). In this case, the measurement control unit 148 performs A / D conversion on the analog data from the sensor unit 149 to obtain temperature data. And the measurement control part 148 records the temperature data measured in this way with the time data sent from the timepiece control part 141 in three types of formats.
[0028]
That is, the measurement control unit 148 writes temperature data in the temperature history memory 146. When the data is read from the cool memory 3 by the personal computer 1 as will be described later, a time stamp calculated from the measurement start date and time and the measurement interval is added to the temperature data in the temperature history memory 146. In addition, the measurement control unit 148 divides the food temperature into zones (for example, 0 ° C. or lower zone, 0 ° C. to + 5 ° C. zone, + 5 ° C. to + 10 ° C. zone, + 10 ° C. to + 15 ° C. zone, + 20 ° C. or higher). The measured temperature data is distributed to each zone and counted, thereby creating a histogram and writing it in the histogram memory 144.
[0029]
In this case, for example, if the food temperature is 0 ° C. or less once, the zone of 0 ° C. or less is set to 1, and if it is 0 ° C. to + 5 ° C. 100 times, the zone of 0 ° C. to + 5 ° C. is set. 100, if it was + 5 ° C to + 10 ° C 10,000 times, the zone of + 5 ° C to + 10 ° C was set to 10,000, and if it was + 10 ° C to + 15 ° C 10 times, the zone of + 10 ° C to + 15 ° C was 10 and if the temperature becomes + 20 ° C. or higher once, the zone of + 20 ° C. or higher is set to 1.
[0030]
The temperature alarm memory 143 records temperature alarm data. In this case, as will be described later, the temperature alarm includes a high temperature alarm when the temperature alarm upper limit is exceeded and a low temperature alarm when the temperature alarm is lower than the lower limit, and the temperature alarm memory 143 ends when each alarm occurs. The date and time are recorded.
[0031]
When the food is delivered to the store, the cool memory 3 is taken out of the container and inserted into the storage unit 11 of the button reader 2. As a result, the cool memory 3 is connected to the signal line 17, and data can be transmitted to and received from the personal computer 1.
[0032]
Here, the ID code of the cool memory 3 itself and the identification data indicating that it is the cool memory 3 are written in the ID section 133 built in the cool memory 3, and data communication with the personal computer 1 is performed in the memory 138. A communication protocol to be performed is stored. Further, for example, various setting data to be described later is written in the memory 137. The memory 138 is a memory that can be used by the user. In this case, software for displaying the data in the memories 143, 144, and 146 on the personal computer 1 may be written in advance. Reduces the burden on the personal computer 1 side.
[0033]
Next, the holding member 24 of the cool memory 3 will be described with reference to FIGS. The holding member 24 is used for facilitating the handling of the small cool memory 3 as described above. Each of the holding members 24 is formed of a main body 52 formed of a heat insulating hard synthetic resin such as 66 nylon and the main body 52. The holder 53 is detachably attached. Further, the main body 52 and the holder 53 have a relatively conspicuous color such as red, for example, thereby improving the position confirmation and avoiding loss.
[0034]
24 and 25 show a perspective view and a longitudinal side view of the holding member 51 with the holder 53 attached to the main body 52, respectively. 27 to 29 show a front view, a side view, and a longitudinal side view of the holder 53, respectively. The holder 53 has a thin plate shape with one end curved, and as a whole, the holder 53 is bent into a substantially “<” shape. A circular holding hole 54 as a holding portion is formed at one end of the holder 53, and the one end edge further protrudes from the back side to form a thin insertion portion 56. An engaging portion 57 is formed at the other end of the holder 53 at a predetermined distance from the holding hole 54, and a smooth display is provided on the surface between the engaging portion 57 and the holding hole 54. A portion 58 is formed.
[0035]
For example, a sticker (not shown) in which predetermined information such as the use and location of the cool memory 3 and the ID code is described can be attached to the display unit 58. Further, the inner diameter of the holding hole 54 is dimensioned so that the case 3A of the cool memory 3 can be detachably fitted into the holder hole 54, and the inner surface of the holding hole 54 is the case when the cool memory 3 is inserted. The shape is such that the side surface of 3A is fastened. Further, the rear surface side of the holding hole 54 is further expanded to form an expanded portion 54A, in which the flange portion 3B of the cool memory 3 is accommodated and abutted.
[0036]
On the other hand, FIGS. 26 and 30 to 32 show a back view, a front view, a side view, and a longitudinal side view of the main body 52, respectively. The main body 52 has a predetermined thickness, and a receiving portion 61 having a shape substantially matching the shape of the holder 53 is formed on the front surface of the main body 52 in order to store the holder 53. Further, an insertion portion 62 is formed at one end edge of the housing portion 61, and an engaged portion 63 is formed at the other end edge, and a screw hole 64 as a mounting portion is once recessed at one end portion of the housing portion 61. After that, the penetration is formed. Further, a screw hole 66 as an attachment portion is also formed through the other end portion of the main body 52.
[0037]
Further, on both sides of the accommodating portion 61 between the screw hole 64 and the engaged portion 63, recesses 67 and 67 are formed so as to be inclined downwardly outward. Furthermore, a rectangular recess 68 is formed on the back surface of the main body 52. In the recess 68, a magnet MG as a mounting portion is housed and pasted.
[0038]
With the above configuration, for example, the main body 52 of the holding member 51 is first attached and placed on the inner wall surface (attachment surface) of the container. At that time, when the container is made of a magnetic material such as metal, the magnet MG is attracted to the inner wall surface of the container to fix the back surface of the main body 52 to the inner wall surface of the container. Further, when the container is not a magnetic body or when it is desired to securely fix the container, a screw (not shown) is inserted into the screw holes 64 and 66 and screwed into the inner wall surface of the container, and the main body 52 is attached to the inner wall surface of the container. Fix it. At this time, the head of the screw is housed in the recessed portion of the screw hole 64, and therefore does not protrude from the housing portion 61.
[0039]
On the other hand, the cool memory 3 is detachably fitted into the holding hole 54 of the holder 53 from the back surface. At this time, as described above, the flange portion 3B of the cool memory 3 abuts on the stepped portion 54A of the holding hole 54, and the bottom surface is substantially flush with the back surface of the holder 53. Further, the case 3A of the cool memory 3 is tightened from the side surface and is stably held in the holding hole 54, and in this state, the upper surface side of the cool memory 3 protrudes at least half or more from the front side of the holder 53.
[0040]
Here, since the holder 53 has a “<” shape as described above, the cool memory 3 can be brought into contact with the placement surface if it is placed with the back side down while holding the cool memory 3. And can be held away from the mounting surface. Therefore, it is possible to prevent the cool memory 3 from directly detecting the temperature of the mounting surface in this state.
[0041]
Then, with the cool memory 3 held in the holder 53 as described above, the back surface of the holder 53 is made to correspond to the accommodating portion 61 of the main body 52, and both edge portions of the display portion 58 of the holder 53 are sandwiched between fingers, 33, the insertion portion 56 at one end is inserted into the insertion portion 62 of the main body 52 as indicated by a solid arrow. Next, as shown by a broken line arrow in FIG. 33, the holder 53 is pressed against the main body 52, and the engaging portion 57 at the other end is engaged with the engaged portion 63 of the main body 52. At this time, since both ends of the holder 53 are stretched, the holder 53 is stably and detachably attached in the accommodating portion 61 of the main body 52 (FIG. 24).
[0042]
In addition, the rear portion of the cool memory 3 has a shape in which the accommodating portion 61 of the main body 52 corresponds, and the collar portion 3B of the cool memory 3 contacts the stepped portion 54A. It becomes impossible to move and it is reliably prevented from falling off. As described above, the cool memory 3 attached to the container via the holder 53 and the main body 52 of the holding member 51 performs an operation of recording the ambient temperature as described above.
[0043]
On the other hand, when removing the holder 53 from the main body 52 in FIG. 24, the both edge portions of the display portion 58 are similarly held between fingers. At this time, since the recesses 67 and 67 are formed on both sides of the accommodating portion 61 of the main body 52, it is easy to hook a finger on the back side of the holder 53. First, the other end of the holder 53 is pulled away from the main body 52 to remove the engaging portion 57 from the engaged portion 63, and then the insertion portion 56 is pulled out from the insertion portion 62. Thereby, the holder 53 can be attached to and detached from the main body 52 without touching the cool memory 3. Needless to say, the holder 53 can be handled without touching the cool memory 3 even when the holder 53 is attached to the main body 52.
[0044]
Next, reading of data from the cool memory 3 using the personal computer 1 and setting of data in the cool memory 3 will be described. First, at the start of reading data from the cool memory 3, the control program of the personal computer 1 is activated. Then, when an unillustrated icon using the cool memory 3 displayed on the CRT display 6 is clicked with the mouse 9, the CPU 31 displays a status display screen shown in FIG.
[0045]
Next, as described above, the holder 53 is detached from the main body 52 of the holding member 51 and taken out from the container, and while holding the cool memory 3 in the holder 53, hold the other end of the holder 53 and hold the upper surface side of the cool memory 3. Insert into the storage part 11 of the button reader 2. Accordingly, the cool memory 3 can be attached to the button reader 2 without touching the cool memory 3.
[0046]
At this time, it is assumed that three cool memories 3... Are installed. When the “search” frame in the status display screen of FIG. 5 is clicked with the mouse 9, the CPU 31 selects the cool memories 3. Scan (search).
[0047]
This scanning operation is performed by reading the ID code written in the ID section 133 of each cool memory 3. The CPU 31 identifies the connection status of the three cool memories 3... By the ID codes collected by scanning, temporarily holds these ID codes in the memory 32, and thereafter uses the ID codes to each cool memory 3.・ Transmit data to and from. The collected ID codes are listed up in the “Select Cool Memory” field on the status display screen of FIG.
[0048]
If the down arrow button of this “Cool memory selection” field is clicked with the mouse 9, the ID codes of the respective cool memories 3... Searched as shown in FIG. By clicking, the cool memory 3 for reading and writing data can be selected.
[0049]
When any one of the cool memories 3 connected to the button reader 2 is selected in this way, the CPU 31 displays the operating state of the cool memory 3 in the “operating state” frame of the display screen of FIG. At this time, the CPU 31 polls the selected cool memory 3 and requests transmission of various setting data relating to the operation of the cool memory 3.
[0050]
The memory control unit 136 of the cool memory 3 receives various setting data written in the memory 137 in response to polling from the personal computer 1 and time data of the clock control unit 141 via the signal line 17 by the interface 132. Send to.
[0051]
The CPU 31 of the personal computer 1 once writes the data transmitted from the cool memory 3 in the memory 32, and then displays the operating status of the cool memory 3 in the “operating status” frame of the status display screen of FIG. 5 displayed on the CRT display 6. indicate. In this case, the CPU 31 displays whether the cool memory 3 is currently operating or stopped in the “operating state” column of the “operating state” frame.
[0052]
The “remaining standby time” column displays the remaining standby time until the temperature measurement is started, and the “measurement start time” column displays the temperature measurement start date and time. The “Measurement interval” column displays the temperature measurement interval (sampling period), and the “Measurement data number” column displays the total number of data measured from the start of measurement until the present. The number of data stored in each memory 146 is displayed in the “number of data” column.
[0053]
Further, in the “memory overwrite” column, a setting state of whether or not new data is overwritten when the data amount of each memory is saturated is displayed. In other words, when overwriting is set, the old data is discarded when the data amount is full, and new data is written, and when it is set to no, the data becomes full. At this point, the cool memory 3 stops the recording operation. In the “Memory Overwrite Occurrence” column, whether or not the data in each memory is overwritten during measurement is displayed (present / not present).
[0054]
Furthermore, the upper limit temperature of the temperature alarm is displayed in the “temperature alarm upper limit” column, and the lower limit temperature of the temperature alarm is displayed in the “temperature alarm lower limit” column. The “current time” column displays time data (date and time) held by the clock control unit 141 of the cool memory 3, and the “total measurement count” column displays the total temperature measurement up to the present. Display the number of times.
[0055]
Here, in the temperature measurement by the cool memory 3, the work that consumes the most power is A / D conversion in the measurement control unit 148. Therefore, the lifetime of the battery 147 can be determined from the total number of measurements.
[0056]
That is, assuming that the life of the battery 147 is defined as, for example, 500,000 times in terms of the number of measurable times (actually, it can be used more times), the “total measurement count” of the CRT display 6 It can be determined how much the cool memory 3 can be used later depending on whether the total number of measurements displayed in the "" column is close to or far from the 500,000 times.
[0057]
In particular, in the embodiment, when the total number of measurements exceeds, for example, 490,000, the CPU 31 displays the number in the “total measurement count” field in yellow, for example, and when the total number exceeds 500,000, For example, it is displayed on the CRT display 6 in red. As a result, the user can reliably and accurately determine the life of the battery 147 of the cool memory 3.
[0058]
Here, for example, when the cool memory 3 is used in an environment where the ambient temperature is + 50 ° C. or more, there is a possibility that the life of the battery 147 may be shortened due to the self-discharge of the battery 147. Therefore, the measurement control unit 148 of the cool memory 3 writes the number of times of measurement of the temperature of + 50 ° C. or higher in the memory 138. Then, when the number of times of measurement of + 50 ° C. or more is written even once in the memory 138 of the cool memory 3, the CPU 31 displays “!”, For example, adjacent to the number in the “total measurement count” column. .
[0059]
As a result, the user can accurately recognize that there is a possibility that the cool memory 3 cannot be used for the predetermined number of measurements of 500,000 times. The display symbol may be another symbol, and may be identified by the display color without being limited to the symbol. In the “memo” column, the contents of a predetermined memo such as a measurement location written as described later are displayed.
[0060]
Next, when the “measurement result” frame is clicked on the display screen of FIG. 5, the CPU 31 displays the operation result display screen of FIG. 8 as a dialog on the CRT display 6. At this time, the CPU 31 polls the selected cool memory 3 and requests transmission of temperature data recorded by the cool memory 3. In response to the polling from the personal computer 1, the memory control unit 136 of the cool memory 3 transmits the data in the temperature alarm memory 143, the histogram memory 144, and the temperature history memory 146 to the personal computer 1 through the signal line 17 by the interface 132. .
[0061]
The CPU 31 of the personal computer 1 once writes the data transmitted from the cool memory 3 in the memory 32 and then displays it on the operation result display screen of FIG. 8 displayed on the CRT display 6. In this case, the CPU 31 displays the temperature data in the temperature history memory 146 (data to which a time stamp is added as described above) as a numerical value in the “temperature data” column, and the histogram data in the histogram memory 144 is displayed as “temperature distribution”. A numerical value is displayed in the column, and data in the temperature alarm memory 143 is also displayed in the alarm column (displayed by the start date and end date and time of the high temperature and low temperature).
[0062]
When the “graph” frame in the “temperature data” column is clicked with the mouse 9 in this state, the CPU 31 displays the temperature data graph display screen shown in FIG. 9 on the CRT display 6. In this screen, the horizontal axis is time (in the example, 5:18 on May 11 to 5:18 on May 15), and the vertical axis is the temperature (in the example, the maximum scale is 30 ° C., the minimum scale is 0 ° C.). Thus, the transition (history) of the recorded temperature is displayed by the line L1. Thereby, it is possible to grasp the temperature transition of the transported food in which the cool memory 3 is inserted.
[0063]
Further, on this graph display screen, the CPU 31 sets the background color of the high temperature alarm area above the temperature alarm upper limit to, for example, red, and the background color of the low temperature alarm area below the temperature alarm lower limit, for example, to blue. As a result, it is possible to easily identify a time zone that exceeds the upper and lower limits of the temperature alarm in the course of temperature transition.
[0064]
Next, when the “vertical axis change” frame in the display screen of FIG. 9 is clicked, the CPU 31 displays the vertical axis change screen of FIG. 10 on the CRT display 6. In this screen, in addition to the screen of FIG. 9, “Change vertical axis: from” is displayed. When the mouse 9 is clicked on, for example, around 21 ° C. on the screen of FIG. 10, the CPU 31 displays the screen of FIG. 11 on the CRT display 6. In the screen of FIG. 11, a horizontal line L2 is displayed at 21 ° C. on the graph, and “change in vertical axis: how far” is displayed.
[0065]
Next, when the vicinity of 14 degrees, for example, is clicked on the screen of FIG. 11, the CPU 31 displays the screen of FIG. 12 on the CRT display 6. In the screen of FIG. 12, the maximum scale on the vertical axis is displayed as 21 ° C., and the minimum scale is displayed as 14 ° C. As a result, the range of 14 ° C. to 21 ° C. of the graph displayed in FIG. 9 is enlarged and displayed. 12 is clicked, the CPU 31 returns the screen display to the same screen as shown in FIG. 9 (shown in FIG. 13).
[0066]
Next, when the “horizontal axis change” frame in the display screen of FIG. 13 is clicked, the CPU 31 displays the horizontal axis change screen of FIG. 14 on the CRT display 6. In this screen, in addition to the screen shown in FIG. 13, “change horizontal axis: where” is displayed. When the mouse 9 is clicked on the screen shown in FIG. 14 near the low-priority at 5:18 on May 13, for example, the CPU 31 displays the screen shown in FIG. In the screen of FIG. 15, a vertical line L3 is displayed near the front of May 13 on the graph, and “change in horizontal axis: how far” is displayed.
[0067]
Next, on the screen shown in FIG. 15, for example, when the vicinity of 5:18 on May 14 is clicked, the CPU 31 displays the screen shown in FIG. 16 on the CRT display 6. In the screen of FIG. 16, the left end of the horizontal axis is displayed as 4:30 on May 12, and the right end is displayed as 4:30 on May 14. As a result, the range of 4:30 on May 12 to 4:30 on May 14 is enlarged and displayed in the graph displayed in FIG. 13 (similar to FIG. 9). If the “return to initial drawing” frame in the screen display of FIG. 16 is clicked, the CPU 31 returns the screen display to the same screen as shown in FIG. 9 (shown in FIG. 13).
[0068]
Next, when the “graph” frame in the “temperature distribution” column of FIG. 8 is clicked with the mouse 9, the CPU 31 displays the temperature distribution graph display screen shown in FIG. 17 on the CRT display 6. In this screen, the recorded histogram is displayed as a bar graph in which the horizontal axis is temperature (−40 ° C. to + 70 ° C. in the embodiment) and the vertical axis is the number of times (0 to 200 times in the embodiment). Thereby, temperature history, such as a conveyed food in which the cool memory 3 was thrown in, can be grasped by a histogram.
[0069]
Next, when the “vertical axis change” frame in the display screen of FIG. 17 is clicked, the CPU 31 displays the vertical axis change screen of FIG. 18 on the CRT display 6. In this screen, in addition to the screen of FIG. 17, “Change vertical axis: Specify maximum value position” is displayed. When the user clicks, for example, about 100 times on the screen of FIG. 18, the CPU 31 displays the screen of FIG. 19 on the CRT display 6. In the screen of FIG. 19, the maximum value on the vertical axis is displayed as 100 times (the minimum value is 0 times). Thereby, the range of 0 to 100 times of the bar graph displayed in FIG. 17 is enlarged and displayed. If the “return to initial drawing” frame in the screen display of FIG. 19 is clicked, the CPU 31 returns the screen display to FIG.
[0070]
Thus, when displaying the temperature data recorded corresponding to the time on the CRT display 6, it is possible to enlarge and display an arbitrary range of the graph display, so even if the CRT display 6 is small like a mobile personal computer, It becomes possible to easily check and analyze the graph display of temperature data recorded for a long period of time, and it becomes extremely convenient especially during the transportation of low temperature food. In particular, since it becomes possible to specify a range to be enlarged by clicking the mouse 9 and perform other input operations, the operability is remarkably improved.
[0071]
On the display screen of FIG. 12, FIG. 16, or FIG. 19, the CPU 31 further enlarges and displays the range by designating an arbitrary range by the same operation. That is, the enlarged display can be executed recursively. However, when the “return to initial screen” frame is clicked with the mouse 9, it always returns to the screen of FIG. 9, FIG. 13 or FIG.
[0072]
Next, when the “setting” frame is clicked with the mouse 9 on the display screen of FIG. 5, the CPU 31 displays the start setting screen of FIG. 7 on the CRT display 6. At this time, the CPU 31 displays the time data of the cool memory 3 read as described above in the “current time” column of FIG. This is the time of the clock control unit 141 of the cool memory 3. Further, the time of the personal computer 1 is displayed in the “PC setting time” column.
[0073]
Then, when the “date and time” frame on the display screen of FIG. 7 is clicked, the time of the clock control unit 141 of the cool memory 3 is set to the time of the personal computer 1. Here, since the cool memory 3 is placed in an environment where the temperature change is severe, the time data may be distorted due to the frequency fluctuation of the oscillator 139 or the like. Therefore, when a new temperature recording is started, if there is a discrepancy between the “current time” and “PC set time” displayed on the screen of FIG. By clicking at 9, the time of the cool memory 3 can be set to the time of the personal computer 1.
[0074]
Further, in the “measurement start date and time” column of the display screen of FIG. 7, the temperature measurement start date and time can be set as a numerical value of year, month, date, hour, and minute. When this measurement start date and time is set, the CPU 31 displays a waiting time from the current time to the start of measurement below.
[0075]
Furthermore, in the “measurement interval” column, the temperature measurement interval can be set in units of minutes. When this measurement interval is set, the CPU 31 displays the measurement period until the data amount in the memory 146 of the cool memory 3 is saturated to the right of the maximum memory capacity. In the “memory overwrite” column, it is possible to click whether or not to overwrite the memory as described above. The total measurement count is also displayed on the right side of the “memory overwrite” column.
[0076]
In the “temperature alarm” field, the upper limit temperature for issuing the high temperature alarm and the lower limit temperature for issuing the low temperature alarm can be set. Further, when the “memo input” column is clicked, predetermined memo contents such as measurement locations can be written as described above.
[0077]
When all the setting items have been set, the “setting end” frame in the display screen of FIG. 7 is clicked. When this “setting end” frame is clicked, the CPU 31 transmits various setting data set in FIG. 7 to the signal line 17 together with the ID code of the cool memory 3 through the bus I / O interface 34.
[0078]
When the cool memory 3 receives various setting data with its own ID code by the interface 132, the memory control unit 136 writes the setting data in the memory 137. Thereafter, the cool memory 3 operates according to the various setting data.
[0079]
Here, when delivering a low-temperature article in this kind of convenience store chain or the like, it is necessary to set the same setting data such as the measurement start date and time and the measurement interval in the plurality of cool memories 3. In such a case, the “collective setting” frame is clicked with the mouse 9 on the display screen of FIG. When this “batch setting” frame is clicked, the CPU 31 transmits various setting data set on the screen above it to all the cool memories 3... (Three here) searched in advance.
[0080]
In this case, the CPU 31 sequentially attaches the ID code of each cool memory 3... And sends various setting data to each cool memory 3. This makes it possible to perform the same setting for a plurality of cool memories 3... At a time, so that the setting workability is remarkably improved.
[0081]
Further, in such delivery of low-temperature articles, the setting contents are often patterned depending on, for example, delivery times and delivery distances in the morning, noon, and evening, and storage temperatures of room temperature, freezing, and refrigeration. In such a case, various items are patterned and set as described above on the start setting screen of FIG. When this “memory” frame is clicked, the CPU 31 writes the setting contents in the hard disk 7 in a file format. At this time, the file name is also added and stored.
[0082]
When the “reference” frame on the display screen of FIG. 7 is clicked, the CPU 31 displays the setting content file name written in the hard disk 7 in the window on the CRT display 6 as described above, so that the file name to be set is selected. For example, various setting contents stored in advance are displayed on the display screen of FIG. By clicking on the “collective setting” frame or the “setting completion” frame in this state, the setting contents stored in advance by the CPU 31 are transmitted to each cool memory 3 as described above. Thereby, the setting workability of the cool memory 3 is further improved.
[0083]
Next, when the “file” frame is clicked with the mouse on the display screen of FIG. 5, the CPU 31 displays a “file output” frame as shown in FIG. When this “file output” frame is clicked, the CPU 31 displays a save screen with the file name shown in FIG. 21 on the CRT display 6. If a file location and a file name are input on this screen and a “save” frame is clicked, the CPU 31 saves the temperature data and alarm data read from the selected cool memory 3 in the hard disk 7 in a file format.
[0084]
Here, when the alarm confirmation software of the personal computer 1 is activated, the CPU 31 displays an alarm confirmation dialog “Set Cool Memory” in FIG. 22 on the CRT display 6. In this state, when one cool memory 3 is stored and connected to the storage unit 11 of the button reader 2, the CPU 31 automatically polls the cool memory 3 and transmits data in the temperature alarm memory 143 of the cool memory 3. Request.
[0085]
In response to the polling from the personal computer 1, the memory control unit 136 of the cool memory 3 transmits the data in the temperature alarm memory 143 to the personal computer 1 through the signal line 17 through the interface 132. When the CPU 31 of the personal computer 1 includes at least one high or low temperature alarm data in the data transmitted from the cool memory 3, that is, the temperature data in the cool memory 3 exceeds the upper limit temperature even once, or If there is a history of lower than the lower limit temperature, “abnormal” is displayed together with the ID code (ID number) and memo of the cool memory 3 in the alarm confirmation dialog of the CRT display 6 as shown in FIG.
[0086]
When there is no temperature alarm data in the temperature alarm memory 143, the CPU 31 displays “Normal” in the alarm confirmation dialog. Thereby, the user can easily and quickly confirm that the temperature alarm is generated in the cool memory 3. The detailed operation result may be confirmed on the operation result display screen.
[0087]
Note that, for example, during the pull-down immediately after the start of operation of the low-temperature delivery vehicle or during loading in the low-temperature delivery vehicle, the surroundings of the cool memory 3 are also temporarily high but relatively high (for example, normal temperature). It becomes. Even in such a case, the temperature alarm data 143 in the cool memory 3 is written with the temperature alarm data. However, in the alarm confirmation work as described above, it is rather confusing to issue an alarm in such a situation. Become.
[0088]
Therefore, by setting the time in minutes in the “alarm delay” column on the start setting display screen of FIG. 7, the alarm delay time from the start of measurement and from the occurrence of an abnormality can be set. That is, for example, when a delay time of 10 minutes (can be set in the range of 1 to 10 minutes) is set in this “alarm delay” column, this set value is stored in the memory 32 of the personal computer 1 or the hard disk 7. . When the personal computer 1 reads the data from the cool memory 3 and the temperature alarm data 143 is written in the temperature alarm memory 143 of the cool memory 3, the data exceeds, for example, the upper limit temperature or the lower limit. If the temperature falls below the temperature and returns to the normal range (temperature range lower than the upper limit temperature and higher than the lower limit temperature) within 10 minutes from the start of the state, the CPU 31 ignores the alarm data.
[0089]
As a result, it is possible to prevent the occurrence of a temperature abnormality or a temporary temperature abnormality during pull-down or loading as described above in the alarm check operation.
[0090]
In the present invention, temperature recording and reading can be performed without using the holding member 51 without touching the cool memory 3, but in addition to or instead of this, by appropriately setting the measurement start and end times. Needless to say, it is also possible to invalidate the temperature recording when the cool memory 3 is inserted into the recording target and when it is attached to the button reader 2. If the setting is performed in addition to the use of the holding member 51, the inconvenience that the cool memory 3 measures abnormal data can be avoided more reliably.
[0091]
【The invention's effect】
As described above in detail, according to the present invention, the temperature detection means for detecting the temperature of the recording object, the recording side storage means for holding its own ID code, the clock means, the transmission / reception means for exchanging data with the outside, The recording means for recording the temperature data detected by the temperature detection means in correspondence with the time and the power source are housed in the case, and the temperature recording device for recording the temperature around the case is held in the holding portion of the holding member Therefore, even if the temperature recording device is small, it can be handled easily.
[0092]
Also, The present invention According to the present invention, the holding member is composed of a main body having an attachment portion for attaching to the attachment surface and a holder having the holding portion, and the temperature recording device is held in the holding portion with the temperature recording device being held in the temperature recording device. Since the holder can be detachably attached to the main body without being touched, it is possible to avoid the disadvantage that abnormal temperature data is recorded in the temperature recording device. For example, when performing temperature recording with the temperature recording device fixed to a fixed point, the main body is attached to the mounting surface and the temperature recording device is held by the holder, and the holder is attached to the main body without touching the temperature recording device. Can be attached to or detached from the main body, and the temperature recording apparatus can be handled more easily and safely.
[0093]
In particular, the holder of the holding member As a whole, it has the shape of “ku”, When removed from the main body and placed on the placement surface, the temperature recording device is kept away from the placement surface. Can be held Therefore, even when the holder is detached from the main body and placed on the placement surface, it is possible to avoid inconvenience that the temperature recording apparatus directly affects the temperature recording device directly from the placement surface.
[0094]
According to the invention of claim 2, in addition to the above, since the holding member is made of a heat insulating material, the holding member itself is transmitted to avoid the disadvantage of adversely affecting the temperature recording apparatus. It becomes possible to reduce. As a result, by using the holding member of the present invention as a whole, accurate temperature recording by the temperature recording device can be achieved.
[0095]
Furthermore, according to the invention of claim 3, in addition to the above inventions, the temperature recording device of the holding unit is held away from the mounting surface in a state of being mounted on the mounting surface by the mounting portion. For example, when measuring temperature data with the temperature recording device fixed at a fixed point, the temperature recording device can be easily attached to the attachment surface using the attachment portion of the holding member. In particular, since the temperature recording device is held away from the mounting surface in the mounted state, inconveniences that adversely affect the temperature directly from the mounting surface to the temperature recording device can be avoided in advance. The temperature can be recorded reliably.
[0096]
According to the invention of claim 4, since the attachment portion is constituted by a screw hole in each of the above inventions, screwing and fixing to the attachment surface is facilitated, and according to the invention of claim 5, Since the attachment portion is composed of a magnet, the fixing work when the attachment surface is a magnetic body is extremely easy.
[0097]
According to the invention of claim 6, in addition to the above inventions, the holder is provided with a display portion for displaying predetermined information relating to the temperature recording device. In addition, the temperature recording device can be easily identified by displaying and setting the installation location.
[Brief description of the drawings]
FIG. 1 is a perspective view of a personal computer and a button reader constituting a temperature recording system of an embodiment to which the present invention is applied.
FIG. 2 is a block diagram of an electric circuit of a personal computer.
FIG. 3 is a perspective view of a cool memory as a temperature recording device.
FIG. 4 is a block diagram of an electric circuit of a cool memory.
FIG. 5 is a diagram showing a status display screen displayed on a CRT display of a personal computer.
FIG. 6 is another diagram showing a status display screen displayed on the CRT display of the personal computer.
FIG. 7 is a diagram showing a start setting screen displayed on a CRT display of a personal computer.
FIG. 8 is a diagram showing an operation result display screen displayed on a CRT display of a personal computer.
FIG. 9 is a diagram showing a temperature data graph display screen displayed on a CRT display of a personal computer.
FIG. 10 is a view showing a temperature data graph display screen similarly displayed on the CRT display of the personal computer.
FIG. 11 is a diagram showing a temperature data graph display screen similarly displayed on the CRT display of the personal computer.
FIG. 12 is a diagram showing a temperature data graph display screen similarly displayed on the CRT display of the personal computer.
FIG. 13 is a view showing a temperature data graph display screen similarly displayed on the CRT display of the personal computer.
FIG. 14 is a diagram showing a temperature data graph display screen similarly displayed on the CRT display of the personal computer.
FIG. 15 is a view showing a temperature data graph display screen similarly displayed on the CRT display of the personal computer.
FIG. 16 is a diagram showing a temperature data graph display screen similarly displayed on the CRT display of the personal computer.
FIG. 17 is a diagram showing a temperature distribution graph display screen displayed on a CRT display of a personal computer.
FIG. 18 is a diagram showing a temperature distribution graph display screen similarly displayed on the CRT display of the personal computer.
FIG. 19 is a diagram showing a temperature distribution graph display screen similarly displayed on the CRT display of the personal computer.
FIG. 20 is still another diagram showing a status display screen displayed on the CRT display of the personal computer.
FIG. 21 is a diagram showing a temperature data storage display screen displayed on a CRT display of a personal computer.
FIG. 22 is a diagram showing an alarm confirmation screen displayed on a CRT display of a personal computer.
FIG. 23 is another diagram showing an alarm confirmation screen displayed on the CRT display of the personal computer.
FIG. 24 is a perspective view of the holding member of the present invention in a state where a cool memory is held.
FIG. 25 is a vertical side view of the holding member in a state where a cool memory is held.
FIG. 26 is a rear view of the main body of the holding member.
FIG. 27 is a front view of a holder of a holding member.
FIG. 28 is a side view of the holder.
FIG. 29 is a vertical sectional side view of a holder.
FIG. 30 is a front view of the main body of the holding member.
FIG. 31 is a side view of the main body.
FIG. 32 is a vertical side view of the main body.
FIG. 33 is an exploded perspective view of a holding member for explaining a procedure for attaching the holder to the main body.
[Explanation of symbols]
1 PC
2 button reader
3 Cool memory (temperature recording device)
4 Keyboard
6 CRT display
7 Hard disk
9 Mouse
11 Storage section
17 Signal line
31 CPU
32 memory
34 Bus I / O interface
51 Holding member
52 body
53 holder
54 Holding hole (holding part)
56 Insertion part
57 engaging part
58 display
62 Plug
63 engaged part
64, 66 screw holes
132 Interface (Recording side transmission / reception means)
136 Memory control unit
139 Oscillator
141 Clock control unit
143 Temperature alarm memory
144 Histogram memory
146 Temperature history memory
149 Sensor part (temperature detection means)
MG magnet

Claims (6)

Data is exchanged between the main body having a mounting portion for mounting on the mounting surface, temperature detecting means for detecting the temperature of the recording target, recording-side storage means having its own ID code, clock means, and the outside. A transmission / reception means, a recording means for recording the temperature data detected by the temperature detection means in correspondence with the time, and a power supply are housed in the case, and a holding unit for holding a temperature recording device for recording the temperature around the case. Consisting of a holder with
The holder is detachably attachable to the main body without touching the temperature recording device in a state where the temperature recording device is held by the holding portion, and has a generally "<" shape as a whole. For a temperature recording apparatus, wherein the temperature recording apparatus has a bent shape and is capable of holding the temperature recording apparatus in a state of being separated from the mounting surface when it is removed from the main body and mounted on the mounting surface. Holding member.   The temperature recording apparatus holding member according to claim 1, wherein the holding portion is made of a heat insulating material.   The temperature recording device holding member according to claim 1 or 2, wherein the temperature recording device of the holding portion is held apart from the mounting surface in a state of being attached to the attachment surface by the attachment portion.   4. The temperature recording device holding member according to claim 1, wherein the mounting portion is formed by a screw hole.   4. The holding member for a temperature recording apparatus according to claim 1, wherein the mounting portion is made of a magnet.   6. The temperature recording apparatus according to claim 1, wherein the holder is provided with a display unit for displaying predetermined information about the temperature recording apparatus. Holding member.

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