KR102580553B1 - Pharmaceutical Transport Monitoring System - Google Patents

Abstract

The present invention is a system that monitors the transport process of an object that is moved to a second terminal along with a first terminal. The internal space is created as a pre-stored standard environment, and the storage unit for storing the object therein and the transport environment within the storage unit are provided. A real-time measuring unit that measures and transmits first information and second information about the transportation environment to the first and second terminals, respectively, and compares the first information and second information and converts the second information into third information based on the comparison result. It includes a correction unit that changes it to and transmits it to the second terminal. Through the present invention, it is possible to accurately determine the transport process of an object provided as a pharmaceutical in real time, thereby maximizing convenience and safety, and preventing deterioration of the object in advance while also preventing the time and cause of deterioration of the object that may occur. can be easily identified, and a situation in which the owner of the first terminal transporting the object has to pay unfair compensation due to deterioration of the object can be prevented in advance.

Description

Pharmaceutical Transport Monitoring System

The present invention relates to a pharmaceutical transport monitoring system. More specifically, the present invention relates to a system that can more accurately and conveniently determine the status of an object provided as a medicine in real time during the process of transporting the object.

As logistics services become more advanced and diversified, precise management of logistics during transportation or storage is emerging. In particular, in the case of pharmaceuticals, a specific storage environment such as temperature and humidity must be created to prevent deterioration, so the need for transportation safety of pharmaceuticals that are difficult to transport and store has continued to be required. In addition, there is a demand for the distribution of systems that can guarantee safety in the process of transporting medicines. Therefore, the process of transporting medicines can be easily checked, the responsible party can be easily identified in case of deterioration during the transport process, and the transfer of medicines and abnormalities in the transport environment can be easily detected through cross-checking between the transporter and the pharmacist receiving the medicines. There is a need to develop a system that can detect the presence or absence of it.

The problem to be solved by the present invention reflects the development needs described above, and is to facilitate the transportation of pharmaceuticals.

In addition, the purpose of the present invention is to create an optimal drug transport environment and immediately recognize if an abnormality occurs in the process of maintaining it.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned can be clearly understood by those skilled in the art from the description below.

The present invention is intended to solve the above problems, and is a system that monitors the transport process of an object that is moved to a second terminal along with a first terminal, and creates an internal space as a pre-stored reference environment to store the object therein. A real-time measurement unit that measures the transport environment within the storage unit and transmits first and second information about the transport environment to the first and second terminals, respectively, and compares the first and second information and compares the comparison results. It includes a correction unit that changes the second information into third information based on and transmits it to the second terminal.

Through the present invention, the transport process of objects provided as pharmaceuticals can be accurately identified in real time, thereby maximizing convenience and safety.

In addition, according to the present invention, while preventing deterioration of an object in advance, it is possible to easily determine the time and cause of deterioration of the object, which may possibly occur.

In addition, the present invention can prevent a situation in which the owner of the first terminal transporting the object has to pay unfair compensation due to the deterioration of the object.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

1 is a diagram illustrating the overall pharmaceutical transport monitoring system according to an embodiment of the present invention.
Figure 2 is a diagram showing the connection relationship between components in the pharmaceutical transport monitoring system according to an embodiment of the present invention.
Figure 3 is a diagram showing the entire transport unit according to an embodiment of the present invention.
Figure 4 is a diagram showing the interior of a carrying unit according to an embodiment of the present invention.
Figure 5 is a diagram showing the process of forming first information and second information by a real-time measurement unit according to an embodiment of the present invention.
Figure 6 is a diagram showing a graph regarding the transportation environment measured by a real-time measurement unit according to an embodiment of the present invention.
Figure 7 is a diagram showing the storage unit according to an embodiment of the present invention being installed and moved in the guide unit.
Figure 8 is a diagram showing the location of the storage unit recognized by the recognition unit according to an embodiment of the present invention.
Figure 9 is a diagram showing a cross section of a recognition unit according to an embodiment of the present invention.
Figure 10 is a diagram showing an attachment portion according to an embodiment of the present invention.
Figure 11 is a diagram showing a distinguishing tip installed on the storage unit by an attachment unit according to an embodiment of the present invention.
Figure 12 is a diagram showing the process of recognizing the storage unit, measuring the transport environment, and arranging the distinguishing tip according to an embodiment of the present invention.
Figure 13 is a diagram showing that second information is transformed into third information by a correction unit according to an embodiment of the present invention.
Figure 14 is a diagram showing a process for advertising exposure and compensation supply to a second terminal according to an embodiment of the present invention.
Figure 15 is a diagram showing an example of advertisement exposure and compensation supply and demand according to an embodiment of the present invention.

The terminology used herein is for describing embodiments and is not intended to limit the invention. As used herein, singular forms also include plural forms, unless specifically stated otherwise in the context. As used in the specification, “comprises” and/or “comprising” does not exclude the presence or addition of one or more other elements in addition to the mentioned elements. Like reference numerals refer to like elements throughout the specification, and “and/or” includes each and every combination of one or more of the referenced elements. Although “first”, “second”, etc. are used to describe various components, these components are of course not limited by these terms. These terms are merely used to distinguish one component from another. Therefore, it goes without saying that the first component mentioned below may also be a second component within the technical spirit of the present invention.

When it is said that a part "includes" a certain element throughout the specification, this means that, unless specifically stated to the contrary, it does not exclude other elements but may further include other elements. In addition, terms such as "... unit" and "module" used in the specification refer to a unit that processes at least one function or operation, which may be implemented as hardware or software, or as a combination of hardware and software. .

Before explaining the present invention in detail, “one direction” refers to the direction in which the storage unit according to the present invention is inserted into the carrying unit and moves inside, and “the other direction” refers to the direction opposite to the “one direction”. For example, in the case of a transport unit that has entrances and exits facing forward and backward and is installed at the rear of a vehicle, it is preferable that one direction is forward and the other direction is rear. However, depending on the shape of the transport unit, one direction and the other direction may be provided in both side directions. In addition, the “object” is described as being provided as a medicine in one embodiment of the present invention, but the various embodiments are not limited thereto.

Figure 1 is a diagram showing the overall pharmaceutical transport monitoring system according to an embodiment of the present invention, and Figure 2 is a diagram showing the connection relationship between components within the pharmaceutical transport monitoring system according to an embodiment of the present invention.

The pharmaceutical transport monitoring system according to an embodiment of the present invention includes a storage unit 110 for storing objects, transporting the storage unit 110, and providing a space to create a transportation environment for the storage unit 110. A transport unit 100, a real-time measurement unit 120 that measures the transport environment to form first information and second information, and a storage unit 110 for determining whether or not it is properly positioned inside the transport unit 100. When it is determined that the recognition unit 130 and the storage unit 110 are located in the correct position, the attachment unit 140, which attaches the distinguishing tip (d) to the storage unit 110, moves to the first terminal and the second terminal, respectively. When the difference between the first information and the second information is large, it includes a correction unit 150 that changes the second information into third information.

The first terminal and the second terminal are different terminals. The first terminal moves together with the transport unit 100 and delivers the object to the second terminal. That is, the first terminal, the transport unit 100, and the object move together, and in this process, the first information and second information containing information about the inside of the transport unit 100 are transferred to the first terminal and the second terminal, respectively. It is delivered. For example, the first terminal may be a terminal of a transportation driver, and the second terminal may be a terminal owned by a doctor or pharmacist for receiving an object equipped with medicine, but is not limited thereto.

The storage unit 110 is configured to provide a space to store objects and enable easy and safe transportation. For this purpose, the storage unit 110 is provided in the form of a square box and has an open interior to store and accommodate objects. Additionally, the storage unit 110 can store objects therein with the internal space set to a pre-stored standard environment. Here, it is desirable that the storage unit 110 be further equipped with a separate cooling module, dehumidifying module, and dustproof means to create a standard environment inside. Here, the above-mentioned reference environment may include information regarding pre-designated reference temperature, reference humidity, and reference vibration.

In addition, the storage unit 110 may be provided to be stored in a separately provided temperature maintenance cover. That is, the temperature maintenance cover has an open internal space to insert the storage unit 110 and lock it to prevent the temperature of the storage unit 110 from rising or falling excessively, and at the same time, protecting the storage unit 110 from external force. Prevents the pressure from being damped or damaged.

The real-time measurement unit 120 measures the transportation environment within the storage unit 110 and transmits first information and second information according to the measurement results to the first terminal and the second terminal, respectively. To this end, the real-time measurement unit 120 is located inside the transport unit 100 and is connected to the storage unit 110 in communication, and measures the transport environment of the storage unit 110. Here, the real-time measurement unit 120 may be installed inside the transport unit 100 or attached to each storage unit 110 to measure the transport environment related to the interior of the storage unit 110. You can.

The transport environment is implemented for the inside of the storage unit 110, and may include information about the actual temperature, actual humidity, and actual vibration within the storage unit 110. However, the transport environment may also include information about the actual temperature, actual humidity, actual vibration, and actual illuminance within the transport unit 100. In this case, the real-time measurement unit 120 is located inside the transport unit 100 and the storage unit. It may be equipped to measure the transport environment for each interior of 110.

The recognition unit 130 is a component for determining that the storage unit 110 is positioned properly inside the transport unit 100, and is located in an opening space connected to the guide groove 102 within the transport unit 100. In addition, the recognition unit 130 includes a first magnetic body 131, a second magnetic body 132, a coil unit 133, a rod unit 134, and a magnetic force measurement unit 135, and the magnetic force change between the above-described configurations It is determined that the storage unit 110 has entered the interior of the transport unit 100 by recognizing .

The attachment unit 140 is configured to attach the distinguishing tip d in response to the recognition unit 130 recognizing the storage unit 110. For this purpose, the attachment part 140 is located inside the carrying part 100 and maintains the distinguishing tip d mounted in the downward direction. Afterwards, when the recognition unit 130 recognizes the storage unit 110, the lower end of the attachment unit 140 moves downward and attaches the lower discrimination tip d to the storage unit 110.

The correction unit 150 determines whether the second information among the first information and the second information formed by the real-time measurement unit 120 is suitable information. For this purpose, the correction unit 150 stores information about a pre-designated reference interval (a), and the correction unit 150 stores the first and second transportation environments included in the first information and the second information, respectively. Calculate the gap regarding and compare it with the standard gap (a). That is, the correction unit 150 determines whether the information about the actual temperature, actual humidity, and actual vibration included in the first information and the information about the actual temperature, actual humidity, and actual vibration included in the second information are not different from each other. It is a composition that does. This is because the second terminal is connected to the second communication with the real-time measurement unit 120 and receives the second information at predetermined reference times (t), and a difference with the first information transmitted and received in real time inevitably occurs, resulting in a decrease in accuracy. It has the effect of reducing.

Referring to FIG. 2, the functions of the real-time measurement unit 120, recognition unit 130, attachment unit 140, and correction unit 150 are performed on the storage unit 110 in which the object is placed. The following first information and second information move to the first terminal and the second terminal, respectively. Here, the first information and third information may be moved to the first terminal and the second terminal, respectively, depending on the deviation between the first information and the second information.

First, the real-time measurement unit 120 measures the transport environment related to the inside of the storage unit 110 and calculates first information and second information based on this. Afterwards, the recognition unit 130 recognizes that the storage unit 110 is introduced into the carrying unit 100, and the attachment unit 140 uses a distinguishing tip (d) in response to the recognition of the recognition unit 130. Attach to the storage unit 110. Finally, after checking the difference between the first information and the second information, the correction unit 150 considers the second information as inappropriate information when the difference is greater than the standard gap, and determines the third information that is the same as the first information. Form information.

FIG. 3 is a diagram showing the overall transport unit 100 according to an embodiment of the present invention, and FIG. 4 is a diagram showing the interior of the transport unit 100 according to an embodiment of the present invention.

The transport unit 100 is configured to move the storage unit 110 to reach the second terminal. In detail, the transport unit 100 moves the storage unit 110 so that the person who owns the second terminal can reach and receive the object. For this purpose, the inside of the transport unit 100 is opened to accommodate the storage unit 110. In one embodiment of the present invention, a configuration is described in which the rear is opened so that the storage unit 110 can be pushed from the rear to the front and moved through the vehicle, but the present invention is not limited to this and can accommodate a plurality of storage units 110. It can also be provided in the form of a box, box, etc. Meanwhile, the storage unit 110 that has entered the inside of the transport unit 100 moves within the transport unit 100 along the guide unit 101, and in this process, is placed in a position corresponding to the recognition unit 130. The attachment part 140 can attach a distinguishing tip (d) to the storage part 110.

The guide unit 101 provides a path for moving the storage unit 110 within the transport unit 100. For this purpose, the guide unit 101 is provided to extend in a straight direction to move the storage unit 110 in one direction and the other direction, and is provided as a pair to place and move the storage unit 110 between them. In a more preferred embodiment, guide grooves 102 are provided on both side directions of the guide part 101 and engage with the storage part 110, so that the storage part 110 can be moved more easily with less force. there is.

The recognition unit 130 is a component for determining whether the storage unit 110 is in the correct position and recognizes contact with the storage unit 110. For this purpose, the recognition unit 130 is located in the opening space connected to the guide groove 102.

The carrying unit 100 further includes an attachment unit 140. The attachment unit 140 is configured to attach a distinguishing tip d on the upper surface of the storage unit 110 in response to recognition of the storage unit 110, and is connected to the recognition unit 130 in communication. Here, the moment the recognition unit 130 recognizes contact with the storage unit 110, the attachment unit 140, which is provided in a form capable of extending and shortening the length in multiple stages, moves the distinguishing tip (d) disposed at the bottom in a downward direction. Then, the distinguishing tip (d) is attached to the upper surface of the storage unit 110 disposed in the lower direction.

As a more preferred embodiment, the transport unit 100 may be further provided with a light irradiation unit 160 and an illuminance measurement unit 170. The light irradiation unit 160 and the illuminance measurement unit 170 are used to detect changes in the position of the storage unit 110 that may occur during the movement of the transport unit 100 and to detect the occurrence of unfortunate events such as overloading or fire. It is provided. For this purpose, the light irradiation unit 160 and the illuminance measurement unit 170 are located inside the transport unit 100, but the light irradiation unit 160 is located in the upper direction of the transport unit 100 and the illuminance measurement unit 170 ) is located in the lower direction of the carrying unit 100. Additionally, the light irradiation unit 160 is provided to be located directly above the illuminance measurement unit 170. That is, the light irradiation unit 160 and the illuminance measurement unit 170 are arranged perpendicular to the bottom of the transport unit 100. Through this, the illuminance measurement unit 170 can measure the illuminance of the light source generated from the light irradiation unit 160. This can be quickly detected by reducing the size of the measured illuminance when the storage unit 110 is changed to be located between the light irradiation unit 160 and the illuminance measurement unit 170 due to an external force.

Figure 5 is a diagram showing the process of forming first information and second information by the real-time measurement unit 120 according to an embodiment of the present invention, and Figure 6 is a diagram showing the real-time measurement unit 120 according to an embodiment of the present invention. This is a diagram showing a graph about the transportation environment measured by .

The real-time measurement unit 120 is connected to the first terminal and the second terminal, respectively, through the first communication connection and the second communication connection. That is, the first communication connection is a connection between the real-time measurement unit 120 and the first terminal, and the second communication connection is a connection between the real-time measurement unit 120 and the second terminal. As a more preferred embodiment, the first communication connection may be Bluetooth communication and the second communication connection may be GPS-based LTE communication. In other words, the first communication connection is a short-distance communication that enables transmission and reception of first information in real time, and the second communication connection has a longer communication distance than the first communication connection, but transmits and receives second information at a predetermined reference time (t). This is carried out. Here, the reason why the second information is transmitted and received every reference time (t) is to prevent transmission and reception of excessive capacity of the second information.

The storage unit 110 creates a pre-stored reference environment. As described above, the reference environment includes reference temperature, reference humidity, and reference vibration, and related information may be stored separately in the storage unit 110 or in a separately provided storage module.

Afterwards, the real-time measurement unit 120 measures the transportation environment targeting the storage unit 110. In detail, the real-time measurement unit 120 measures the transport environment provided by actual temperature, actual humidity, and actual vibration. Here, the object of the transport environment to be measured is the internal space of the storage unit 110, but it is not limited to this and can also be changed to the inside of the transport unit 100. Meanwhile, when the transport environment measurement is completed, first information and second information based on information about actual temperature, actual humidity, and actual vibration are formed, respectively.

To explain FIG. 6 as an example, FIG. 6A is a graph related to humidity provided as first information, FIG. 6B is a graph related to humidity provided as second information, and the one-dot chain line provided in the graphs of FIGS. 6A and 6B is This refers to the point in time when the real-time measurement unit 120 transmits first information and second information to the first terminal and the second terminal, respectively.

In the case of FIG. 6A, the humidity in the storage unit 110 is measured more frequently compared to FIG. 6B. That is, first information about the transportation environment is transmitted and received in real time between the real-time measurement unit 120 connected to the first communication and the first terminal.

On the other hand, in the case of FIG. 6B, the real-time measurement unit 120 transmits the second information to the second terminal at predetermined reference times (t). In this process, because the second communication connection is GPS-based LTE communication, information about the transportation environment recorded at the same time in the first information and the second information may be different. The hatched portion is the gap between the first information and the second information, and more specifically, the gap regarding the first transport environment included in the first information and the second transport environment included in the second information. The gap regarding the transportation environment between the first information and the second information as described above is calculated by the correction unit 150, and according to the calculation and comparison results, the second information can be discarded and the third information can be formed.

Figure 7 is a diagram showing the storage unit 110 being installed and moved on the guide unit 101 according to an embodiment of the present invention.

As described above, the guide unit 101 provides a path for moving the storage unit 110 within the transport unit 100. For this purpose, the guide portion 101 is provided as a pair to place and move the storage portion 110 between them. In addition, guide grooves 102 are provided on both side directions of the guide part 101 and engage with the storage part 110, so that the storage part 110 can be moved more easily with less force.

As a more preferred embodiment, the storage unit 110 may further include a protrusion 111 for more firmly and easily fastened to the guide unit 101 and for moving the guide. The protrusions 111 are provided as a pair and can be arranged on both sides so as to be integrated with the storage unit 110. Here, the protrusion 111 is provided in a one-to-one correspondence with the guide groove 102 so that it can be inserted. Accordingly, the storage unit 110 can move in one direction and the other direction while the protrusion 111 is inserted into the guide groove 102.

FIG. 8 is a diagram showing that the storage unit 110 is location recognized by the recognition unit 130 according to an embodiment of the present invention, and FIG. 9 is a cross-section of the recognition unit 130 according to an embodiment of the present invention. This is a drawing showing .

The recognition unit 130 determines whether the storage unit 110 is in the correct position through the first magnetic substance 131, the second magnetic substance 132, the coil unit 133, the rod unit 134, and the magnetic force measurement unit 135. can be judged.

The first magnetic material 131 is a component for interaction with the second magnetic material 132, and the first magnetic material 131 maintains a fixed state while causing the position of the second magnetic material 132 to change. For this purpose, the first magnetic material 131 is formed in the open space formed inside the guide portion 101. More specifically, the first magnetic material 131 is located in the opening space formed inside the guide portion 101 to be connected to the guide groove 102 and is provided in the form of a magnet. Here, the first magnetic material 131 is connected to the inner wall of the open space and remains fixed.

The second magnetic material 132 moves its position through interaction with the second magnetic material 132, thereby inducing a change in magnetic force between the coil portion 133 and the rod portion 134, which will be described later. For this purpose, the second magnetic material 132 is provided in the same magnet form as the first magnetic material 131, but is disposed at a predetermined distance from the first magnetic material 131, and is separated from the first magnetic material 131 by a storage unit ( It is located so that it is spaced apart toward 110). That is, the second magnetic material 132 is located between the first magnetic material 131 and the storage unit 110, and is formed to be integrated with the storage unit 110, so that the storage unit 110 corresponds to the protrusion 111 having magnetic force. ) has a configuration that moves toward. In detail, as the size of the protrusion 111 is larger than the size of the first magnetic material 131, the magnitude of the magnetic force possessed by the protrusion 111 is larger than the inherent magnetic force of the first magnetic material 131, and the second magnetic material 132 ) moves within the opening space to approach the protrusion 111 when the storage unit 110 provided with the protrusion 111 approaches.

The coil portion 133 connects the first magnetic material 131 and the second magnetic material 132 to each other and generates magnetic force through interaction with the rod portion 134. For this purpose, the coil portion 133 is provided in a three-dimensional spiral shape and both ends are connected to the first magnetic material 131 and the second magnetic material 132, respectively. In addition, the coil unit 133 is provided with an electromagnet that is supplied with power through a separately provided power supply means and is energized.

The rod portion 134 induces a change in magnetic force according to a change in the length of the coil portion 133 while located in the inner direction of the coil portion 133. For this purpose, the rod portion 134 is located inside the spring-shaped coil portion 133 with a space in the inner direction. In addition, one end of the rod portion 134 is connected to the first magnetic material 131 and the other end is provided so as not to contact the second magnetic material 132.

The magnetic force measuring unit 135 is a component that measures the change in magnetic force between the coil part 133 and the rod part 134, and is located in the opening space and is provided as a magnetic force measuring means for measuring magnetic force.

Referring to FIG. 9A in a state in which the storage unit 110 is not inserted into the guide groove 102, the first magnetic material 131 and the second magnetic material 132 are connected by the coil portion 133 and the coil portion ( 133) is in a reduced state, and the rod portion 134 is located in the inner direction of the coil portion 133, but the other end is not in contact with the second magnetic material 132.

On the other hand, referring to FIG. 9B where the storage unit 110 moves while inserted into the guide groove 102 and the protrusion 111 approaches the opening space, the magnetic force having a magnetic force greater than that of the first magnetic material 131 As the protrusion 111 approaches, the second magnetic material 132 moves toward the storage unit 110. In this process, the length of the coil portion 133 connecting the first magnetic material 131 and the second magnetic material 132 to each other increases, and correspondingly, the coil portion 133 is positioned between one end and the other end of the rod portion 134. ) The number of turns decreases. Through this, the magnetic force between the coil portion 133 and the rod portion 134 decreases, and the magnetic force measuring unit 135 detects the decrease in magnetic force and determines that the storage unit 110 is in the correct position.

Through the first magnetic material 131, the second magnetic material 132, the coil part 133, the rod part 134, and the magnetic force measuring part 135, the plurality of storage parts 110 are connected to the transport part 100. ), it is possible to easily determine whether the storage unit 110 is placed in the correct position without checking with the naked eye during the loading process by pushing it into the inside.

Figure 10 is a diagram showing the attachment part 140 according to an embodiment of the present invention, and Figure 11 is a distinguishing tip installed on the storage unit 110 by the attachment part 140 according to an embodiment of the present invention. This is a drawing showing (d).

As described above, the attachment part 140 is provided to be able to expand and contract in a multi-stage form, and the distinguishing tip d is installed on the storage part 110. For this purpose, the attachment part 140 is installed inside the transport part 100, and the lower end is located in the upper direction of the storage part 110. In addition, a distinction tip (d) is disposed at the bottom of the attachment part 140, and the bottom of the attachment part 140 stores the distinction tip (d) in a vacuum adsorbed state and then stores it in the storage unit ( 110) Release the vacuum suction on the upper surface and install the distinguishing tip (d).

The distinction tip (d) as described above may be provided as a recognition means such as a barcode or QR code that can be recognized by the first terminal and the second terminal, and when the distinction tip (d) is scanned by the first terminal and the second terminal, Information such as the type and capacity of the object provided inside the storage unit 110 can be confirmed.

Figure 12 is a diagram showing the process of recognizing the storage unit 110, measuring the transport environment, and placing the distinguishing tip (d) according to an embodiment of the present invention.

The first terminal forms a first marking part (m1) regarding the object in the storage unit 110 at a first point in time and transmits it to the second terminal. In this process, the first marking unit (m1) includes information such as the type and capacity of the object, transaction information provided by the transaction statement of the object, and code information in the form of a pre-designated number, and the code information is transmitted from the first terminal. It is desirable that they be issued randomly to avoid duplication. In addition, the first time point is when the first terminal scans the storage unit 110. For example, the first time point may be provided before loading the storage unit 110 on the transport unit 100, but is not limited to this. No.

Afterwards, the storage unit 110 containing the object is inserted into the interior of the transport unit 100, and the storage unit 110 is inserted into the interior of the transport unit 100 through the above-described recognition unit 130 and is positioned properly. recognize

Afterwards, the transport environment targeting the storage unit 110 is measured through the real-time measurement unit 120. As described above, the transport environment is related to the actual temperature, actual humidity, and actual vibration within the storage unit 110, and the transport environment for the interior of the storage unit 110 as well as the interior of the transport unit 100 is also related to the real-time measurement unit 120. ) can be measured by .

Thereafter, as the attachment portion 140 located on the upper side of the storage portion 110 descends and attaches the identification tip d, preparations for later identification of the storage portion 110 are completed.

Afterwards, first information and second information are formed through the real-time measurement unit 120 and transmitted to the first terminal and the second terminal. In this process, a first communication connection is established with the first terminal to transmit the first information in real time. A second communication connection is established with the second terminal, and the second information is transmitted at predetermined reference times (t).

Afterwards, the transport unit 100 approaches the second terminal and the storage unit 110 is shipped from the transport unit 100, and the distinguishing tip d is scanned with the second terminal or a separate registration app is run. A second marking portion (m2) can be formed. Here, the second marking part (m2) corresponds to the first marking part (m1) and includes object information, transaction information, and code information in the form of a pre-designated number, but also includes information regarding confirmation completion. You can. Through this, it can be confirmed that the user owning the second terminal has confirmed the safe delivery of the object.

Through the above series of processes, cross-checking of the delivery of objects between the first terminal and the second terminal is possible, thereby significantly increasing safety and reliability.

Figure 13 is a diagram showing that second information is transformed into third information by the correction unit 150 according to an embodiment of the present invention.

As described above in FIG. 6, there is a difference in measurement time and there is a communication delay between the first and second communication connections, so a gap occurs between the first information and the second information (hatched in FIG. 6b) (see section).

The correction unit 150 calculates the gap regarding the first transport environment and the second transport environment included in the first information and the second information based on a predetermined reference interval (a), and compares it with the reference interval (a). do. Thereafter, when the calculated gap between the first information and the second information is greater than the reference interval (a), the correction unit 150 transforms the second information into third information identical to the first information and transmits it to the second terminal. .

Using the graph of FIG. 13 as an example, when the gap between the second information (shown as a dotted line) and the first information (shown as a solid line) is greater than the reference interval (shown as a dashed one-dot line), the correction unit 150 The second information is corrected and formed into third information identical to the first information, and the third information is transmitted to the second terminal.

Through this, by minimizing the gap between the first information and the second information that may arise due to geographical problems or communication connection problems, the user who owns the second terminal can easily accurately determine the status of the transportation environment for the object. there is.

Figure 14 is a diagram showing a process for advertising exposure and compensation supply and demand to a second terminal according to an embodiment of the present invention, and Figure 15 is a diagram showing an example of advertising exposure and compensation supply and demand according to an embodiment of the present invention. am,

In the case of FIG. 15, in order to more easily express information transmission and reception between a plurality of second terminals, it is explained that one second terminal and another second terminal among the plurality of terminals are provided.

In addition, in the case of FIG. 14, the location of the transport unit and the second terminal is calculated by the location measurement unit 210, the theme storage unit 220, the advertisement transmitting and receiving unit 230, and the compensation providing unit 240, which will be described later, and the theme Storing information and sending and receiving advertisements are indicated by ovals and squares so that each subject is distinguished.

As a more preferred embodiment of the present invention, a promotional module 200 may be further included. The promotional module 200 is a component that carries out marketing targeting the second terminal, and may be provided inside the transport unit or may be provided in the form of an external communication module separately connected to a separate communication means provided in the transport unit. Additionally, the promotion module 200 includes a location measurement unit 210, a theme storage unit 220, an advertisement transmission/reception unit 230, and a compensation provision unit 240.

The position measuring unit 210 is a component that measures the positions between the transport unit and the second terminals targeting a plurality of second terminals. More specifically, by detecting that the transport unit is approaching a plurality of second terminals, the advertisement transmitter/receiver 230 transmits an advertisement and allows the target second terminal to receive the advertisement. To this end, the location measurement unit 210 measures the location of the second terminal by receiving signals sent from GPS satellites and calculating the location. At the same time, the position measuring unit 210 detects the position of the carrying unit.

The theme storage unit 220 is provided for the purpose of preventing indiscriminate proliferation of advertisements. To this end, the theme storage unit 220 includes information on a pre-stored theme list and transmits information to inquire about theme selection to the first terminal moving with the transport unit and the second terminal in a fixed location. In response, the first terminal and the second terminal form information about the advertising theme to be promoted and information about the theme of the advertisement to be received, respectively, and return the information to the theme storage unit 220. Through this, the theme storage unit 220 can store themes for the first terminal and the second terminal. Through this, the advertisement stored in the first terminal can be transmitted to the first terminal and the second terminal with the same theme. Additionally, the theme storage unit 220 can determine the theme selected by the second terminal when the first terminal approaches the second terminal. According to the determination result, the advertisement transmitting and receiving unit 230 connected to the theme storage unit 220 transmits information about the advertisement input by the first terminal to the second terminal. Meanwhile, the theme storage unit 220 can receive information about a plurality of themes from the first terminal and the second terminal.

The advertisement transmitting and receiving unit 230 is configured to store advertisements transmitted from the first terminal and simultaneously deliver the advertisements to the second terminal. To this end, the advertisement transceiver 230 may receive a request for advertisement-related information from the first terminal in advance and store it. In a more preferred embodiment, the advertisement transmitter/receiver 230 also receives and stores advertisement-related information in the second terminal, thereby inducing another second terminal to receive advertisements provided from the second terminal.

The reward provision unit 240 is provided to induce activation of advertisements. In detail, the compensation provider 240 provides compensation so that advertisements provided from the first or second terminal are more active. To this end, the compensation provider 240 may request compensation information from the first terminal and the second terminal, and receive and store information about the compensation provided to the first terminal and the second terminal in response. Here, the information regarding the compensation may be provided in various forms such as points that can be used for goods and services, gift certificates, electronic money, etc., but is not limited thereto.

In addition, the compensation provider 240 calculates the cumulative movement distance for the first terminal, calculates the size of the corresponding compensation, and provides the compensation to the first terminal. Here, the cumulative moving distance refers to the distance it takes for the first terminal to reach the second terminal from the same starting point as the transport unit.

15 as an example, the transport unit and the first terminal sequentially move from the first position (L1) to the seventh position (L7) and expose the first advertisement to each of the second terminals (2, 2'). I order it.

First, the first terminal 1 measures the location starting from the first location by the position measuring unit 210, and information about the theme of the first advertisement is stored by the theme storage unit 220, and the first terminal 1 Information about the advertisement is stored in the advertisement transmitting and receiving unit 230, and information about the compensation is provided to the compensation providing unit 240. At the same time, the plurality of second terminals 2, 2' store information about the theme of the advertisement they wish to receive in the theme storage unit 220 and store compensation information in the compensation provision unit 240.

Thereafter, the first terminal (1) approaches one of the second terminals (2) at the fifth position (L5), and the position measuring unit 210 detects the first terminal (1) and one of the second terminals ( 2) By identifying each location, they recognize that they are close to each other. Additionally, the theme storage unit 220 determines which theme is selected for which one of the second terminals 2. Here, when the theme selected by the first terminal 1 and one of the second terminals 2 is the same, the advertisement transceiver 230 transmits the theme to one of the second terminals 2.

At the same time, one second terminal 2 forms a second advertisement to be provided to another second terminal 2 `, and stores information about the second advertisement through the advertisement transmitting and receiving unit 230. do.

If one of the second terminals (2) selects the first advertisement, the compensation providing unit 240 is used to provide the first advertisement to the one of the second terminals (2) by the first terminal (1). The accumulated moving distance for the moved distance, that is, the distance from the first position (L1) to the fifth position (L5), is calculated, and the corresponding compensation size is calculated. Here, the compensation size may be calculated by multiplying the cumulative moving distance by the weight previously stored in the compensation provider 240, but is not limited to this.

The first terminal (1) and the transport unit that have passed the fifth position (L5) move again toward another second terminal (2`), and when they reach the seventh position (L7), they are located in the position measuring unit (210). It is determined that the first terminal and another second terminal (2') are close.

The theme storage unit 220 compares the selected themes of the first terminal (1) and another second terminal (2`). If the selected themes are not the same, the first advertisement is sent to another second terminal (2`). ) is not exposed to

On the other hand, if the selected theme of one second terminal (2) and another second terminal (2`) is the same, the second advertisement is sent to the other second terminal (2`) through the advertisement transmitter and receiver 230. provided. At the same time, another second terminal 2' may additionally transmit and store information about a third advertisement to be provided to another second terminal in the advertisement transmitting/receiving unit 230.

Through the above-mentioned series of configurations and processes, it is possible to exchange necessary information such as advertisements for specific products as well as news related to the object, thereby increasing the usability and versatility of information transmission and reception. In other words, through the present invention, information before being exposed to media, such as media, can be accessed more quickly.

Additionally, by providing compensation, the first or second terminal can be induced to activate advertisement formation and transmission.

Steps such as the method described in connection with the embodiment of the present invention may be implemented directly in hardware, implemented as a software module executed by hardware, or a combination thereof. The software module may be RAM (Random Access Memory), ROM (Read Only Memory), EPROM (Erasable Programmable ROM), EEPROM (Electrically Erasable Programmable ROM), Flash Memory, hard disk, removable disk, CD-ROM, or It may reside on any type of computer-readable recording medium well known in the art to which the present invention pertains.

Above, embodiments of the present invention have been described with reference to the attached drawings, but those skilled in the art will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. You will be able to understand it. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive.

100: transport part 101: guide part
110: storage unit 120: real-time measurement unit
130: Recognition unit 140: Attachment unit
150: correction unit 160: light irradiation unit
170: Illuminance measuring unit

Claims (10)

A system for monitoring the transport process of an object that is moved to a second terminal along with a first terminal,
a storage unit that creates an internal space as a pre-stored standard environment and stores the object therein;
Measure the transport environment within the storage unit, transmit first information about the transport environment to the first terminal through a first communication connection based on short-distance communication, and transmit the transport environment through a second communication connection based on long-distance communication. A real-time measurement unit that transmits second information about to the second terminal at predetermined times;
A gap is calculated by comparing the first transport environment included in the first information and the second transport environment included in the second information, and if the calculated gap is greater than the standard gap, the second information is discarded, and a correction unit that generates third information based on the first information and transmits it to the second terminal;
a transport unit that stores the storage unit inside, moves the storage unit toward the second terminal, and includes a specific communication means; and
a promotional module connected to the first terminal and the second terminal, and receiving information about advertisements from the first terminal and transmitting the information to the second terminal; Characterized by including,
The promotional module is,
a position measuring unit that measures the positions of each of the second terminal and the carrying unit;
a theme storage unit that stores themes selected from the first terminal and the second terminal;
an advertisement transmitting and receiving unit that transmits an advertisement to the second terminal based on whether the second terminal is close to the transport unit and whether the theme selected from each of the first terminal and the second terminal is the same; and
a compensation provider that calculates the cumulative movement distance for the second terminal, calculates the size of the compensation, and provides the calculated compensation;
A pharmaceutical transport monitoring system comprising: According to claim 1,
The reference environment within the storage unit is a predetermined reference temperature, reference humidity, and reference vibration,
A pharmaceutical transport monitoring system, wherein the transport environment is actual temperature, actual humidity, and actual vibration within the storage unit. According to claim 2,
The real-time measurement unit is connected to the first and second terminals through a first communication connection and a second communication connection, respectively,
The first communication connection is Bluetooth communication between the first terminal and the real-time measurement unit,
The second communication connection is a pharmaceutical transport monitoring system, characterized in that LTE communication between the second terminal and the real-time measurement unit. delete delete According to claim 2,
The first terminal forms a first marking part regarding the object in the storage unit at a first point in time and transmits it to the second terminal,
The first marking unit is a pharmaceutical transport monitoring system characterized in that it includes information on the object, transaction information, and code information in the form of a pre-designated number. According to claim 6,
When the object arrives, the second terminal forms a second marking part corresponding to the first marking part and transmits it to the first terminal. According to claim 7,
The transport unit,
A guide part that moves the storage part engaged with the guide groove in one direction and the other direction;
a recognition unit located in an opening space connected to the guide groove and recognizing contact with the storage unit moving along the guide unit; and
A pharmaceutical transport monitoring system comprising: an attachment unit that attaches a distinguishing tip to the upper surface of the storage unit in response to recognition of the storage unit. According to claim 8,
The recognition unit,
a first magnetic body provided in the opening space;
a second magnetic body disposed at a predetermined distance from the first magnetic body;
a coil portion connecting the first magnetic material and the second magnetic material;
a bar portion connected to the first magnetic material at one end and spaced apart from the second magnetic material at the other end, and located in an inner direction of the coil portion; and
It further includes a magnetic force measuring unit that measures the magnetic force between the coil unit and the rod unit,
The second magnetic body moves toward the guide groove in the opening space in response to the approach of the carrying unit,
The magnetic force measuring unit recognizes a magnetic force that decreases in response to a decrease in the number of turns of the coil unit between one end and the other end of the rod unit, and determines the correct position of the storage unit.

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