JP2024022430A - vending machine - Google Patents

Abstract

To provide a technique capable of contributing to greenhouse gas countermeasures by using vending machines as the greenhouse gas countermeasures.SOLUTION: A vending machine includes a CO2 adsorbent. The CO2 adsorbent is provided in a space of the vending machine from which outside air is taken in. The CO2 adsorbent is provided in a space on the lower side of the vending machine from which the outside air is taken in. Alternatively, the CO2 adsorbent is provided on a door that is opened when the vending machine is filled with products. The CO2 adsorbent is provided on a lower side of the door. Further alternatively, the CO2 adsorbent is stored in a storage box provided on the lower side of the door. The storage box is formed of a net member. Furthermore, alternatively, the CO2 adsorbent is stored in a storage bag through which CO2 can pass. The vending machine further includes display means for displaying an amount of CO2 adsorbed by the CO2 adsorbent.SELECTED DRAWING: Figure 1

Description

The present invention relates to a vending machine that sells products such as drinks, and more particularly to a vending machine that has a function of adsorbing CO ₂ (carbon dioxide).

2. Description of the Related Art Conventionally, for example, as disclosed in Patent Document 1, vending machines that sell products such as plastic bottle drinks have been known. This type of vending machine has a housing provided with a door that can be opened and closed, and products are replenished by opening the door.

Patent Document 1 proposes a technique for effectively silencing the driving noise generated by a vending machine in view of the problem of noise when the vending machine is installed in a quiet indoor place such as a hotel or hospital.

Japanese Patent Application Publication No. 2008-210342

Vending machines are installed everywhere outdoors and indoors, and can provide a service that allows consumers to purchase products whenever they want 24 hours a day, and can be said to be socially necessary infrastructure in modern times.

On the other hand, at the Conference of the Parties (COP) to the United Nations Framework Convention on Climate Change, efforts are being made in countries around the world to reduce and absorb greenhouse gas emissions such as carbon dioxide, and people's concerns about global warming are being expressed. continues to rise. In developed countries in particular, there is a strong sense of crisis regarding recent abnormal weather events and rising temperatures, and awareness of greenhouse gases is high not only in government-led initiatives but also at the private company, organization, and individual levels.

While developing products to be sold in vending machines, the inventor realized that vending machines have become a part of social infrastructure, are installed in all parts of the country, are in large numbers, and are used by all types of consumers regardless of age or gender. Focusing on the fact that Japan is a point of contact with people, we examined whether so-called economies of scale could be utilized as a countermeasure against greenhouse gases.

Since vending machines consume electricity and generate heat, they may give off a negative image of contributing to global warming. Furthermore, since there is the problem of noise as mentioned above, vending machines may not have a good image, except for the advantage of being able to purchase products conveniently.

On the other hand, given this negative image, if vending machines can be used to combat greenhouse gas emissions, which is attracting a lot of attention, it can be expected to receive a great response as a result of the negative image gap. . If the response becomes large, it is possible to take advantage of economies of scale and create a social movement.

In view of the above, the present invention provides a technology that utilizes vending machines as a measure against greenhouse gases and can contribute to measures against greenhouse gases.

The problem to be solved by the present invention is as described above, and next, means for solving this problem will be explained.

In one embodiment of the present invention, a vending machine is provided with a CO ₂ adsorbent.

Further, in one form of the present invention, the CO ₂ adsorbent is provided in a space of the vending machine where outside air is taken in.

Further, in one embodiment of the present invention, the CO ₂ adsorbent is provided in a space below the vending machine where outside air is taken in.

Further, in one form of the present invention, the CO ₂ adsorbent is provided on a door that is opened when filling a vending machine with products.

Moreover, in one form of the present invention, the CO ₂ adsorbent is provided at the bottom of the door.

Further, in one embodiment of the present invention, the CO ₂ adsorbent is housed in a storage box provided at the bottom of the door.

Further, in one form of the present invention, the storage box is made of a net member.

Further, in one embodiment of the present invention, the CO ₂ adsorbent is housed in a storage bag through which CO ₂ can pass.

Moreover, in one form of the present invention, a display means for displaying the amount of CO ₂ adsorbed by the CO ₂ adsorbent is provided.

Moreover, in one form of the present invention, it is assumed that a communication means for transmitting or receiving the amount of CO ₂ adsorbed by the CO ₂ adsorbent is provided.

Further, in one embodiment of the present invention, an output means is provided for causing an external terminal to read the amount of CO ₂ adsorbed by the CO ₂ adsorbent.

Moreover, in one form of the present invention, a calculating means for calculating the amount of CO ₂ adsorbed by the CO ₂ adsorbent is provided.

Further, in one form of the present invention, the CO ₂ adsorbent is installed outside the vending machine and installed at a location that comes into contact with the outside air taken into the inside of the vending machine.

Moreover, in one form of the present invention, the CO ₂ adsorbent is installed inside the vending machine and installed at a location that comes into contact with the outside air taken into the inside of the vending machine.

Moreover, in one form of the present invention, the CO ₂ adsorbent is installed inside the vending machine and installed at a location that comes into contact with air released from the inside of the vending machine to the outside.

Further, in one embodiment of the present invention, the CO ₂ adsorbent is installed outside the vending machine and installed at a location in contact with air released from the inside of the vending machine to the outside.

Further, in one form of the present invention, a vending machine includes a heat exchanger through which a refrigerant flows, a fan for taking in outside air, a compressor for compressing the refrigerant, the heat exchanger, the fan, and the compressor. The housing space has an inflow port through which outside air flows in, and an outflow port through which outside _air is discharged. Installed in at least one of the following locations: between the inlet and the heat exchanger, between the heat exchanger and the fan, between the fan and the compressor, and between the compressor and the outlet. , let's say.

Further, in one form of the present invention, the CO ₂ adsorbent is provided outside the casing of the vending machine on at least one of the top plate, side plate, and back plate that constitute the casing. do.

The storage box is made of a material through which gas can pass.

For example, assume that the storage box is made of paper material. In this way, when the storage box is made of a material through which gas can permeate, for example, when it is made of a paper material, the gas is supplied from the surface of the material into the inside of the storage box.

According to the present invention, surrounding CO ₂ can be adsorbed in a vending machine. Vending machines are installed in all parts of the country, and there are many of them, so by taking advantage of this economy of scale, they can greatly contribute to the absorption of CO ₂ from the atmosphere.

FIG. 1 is a perspective view showing an embodiment of a vending machine. FIG. 3 is a perspective view showing the door in an open state. FIG. 3 is a conceptual diagram illustrating acquisition of adsorption factor data, etc. 1 is a flowchart illustrating the steps performed in the present invention. FIG. 3 is a diagram illustrating the adsorption reference amount, collection timing, etc. The figure explaining the example of adsorbing _CO2 in a plurality of vending machines. A schematic diagram illustrating the internal structure of a vending machine. (A) to (C) Diagrams showing examples of placing CO ₂ outside a vending machine.

As shown in FIG. 1, a vending machine 1 according to the present invention is provided with a product from a takeout port 7 when a customer selects a product and pays for the product. The vending machine 1 includes a controller 100 that controls the temperature of products and the operations of various drive units, and automatically sells products according to operations by a customer.

As shown in FIG. 1, the vending machine 1 is equipped with a CO ₂ adsorbent 10.

Thereby, in the vending machine 1, surrounding CO ₂ can be adsorbed. Since the vending machines 1 are installed in all parts of the country in large numbers, by taking advantage of this economy of scale, they can greatly contribute to the adsorption of CO ₂ in the atmosphere.

The CO ₂ adsorbent is preferably provided in a space of the vending machine where outside air is taken in. Further, the CO ₂ adsorbent is preferably provided in a space below the vending machine where outside air is taken in.

As shown in FIGS. 1 and 2, the CO ₂ adsorbent 10 is preferably provided on a door 2 that is opened when filling the vending machine 1 with products. The door 2 is rotatably provided with respect to a housing 6 that is the main body of the vending machine 1.

Thereby, when the door 2 is opened to fill a product such as a PET bottle containing a beverage, the CO ₂ adsorbent 10 can be replaced, and a configuration with excellent workability can be realized.

As shown in FIGS. 1 and 2, the CO ₂ adsorbent 10 is preferably provided at the bottom of the door 2.

As a result, even in a configuration in which the door 2 of the existing vending machine 1 is additionally provided with the CO ₂ adsorbent 10, the center of gravity of the door 2 is placed on the lower side, so the door 2 can be opened and closed stably. (low center of gravity).

As shown in FIG. 2, the CO ₂ adsorbent 10 is accommodated in a storage box 3 provided at the bottom of the door 2, and the storage box 3 is made of a net member.

Thereby, the CO ₂ adsorbent 10 can be easily replaced. Further, the net member is, for example, a stainless steel mesh plate (stainless steel mesh), a net-like plate material, a net capable of supporting an adsorbent, etc., and has air permeability and allows CO ₂ to pass through. Further, the storage box 3 may be made of a material that allows gas to pass through, such as a paper material. When the storage box 3 is made of paper material, _{the CO 2 adsorbent} 10 may be directly stored in the storage box 3 without being placed in the storage bag 4 .

As shown in FIG. 2, the CO ₂ adsorbent 10 is preferably accommodated in a storage bag 4 through which CO ₂ can pass, and in a storage box 3 provided at the bottom of the door 2.

Thereby, the CO ₂ adsorbent 10 placed in the storage bag 4 can be handled as it is in the bag, and the storage bag 4 can be collected as is.

As shown in FIGS. 1 and 2, the CO ₂ adsorbent 10 can be placed near the vent 9 provided at the bottom of the door 2. The vent 9 is for allowing air to pass between the inside and outside of the vending machine 1.

Thereby, CO ₂ in the air moving inside and outside of the vending machine 1 through the vent 9 can be effectively adsorbed.
Originally, vending machines are equipped with devices (e.g. fans) that draw in outside air from the vending machine in order to heat and refrigerate the beverages, foods, etc. that are sold as products. Therefore, outside air can be taken in through the vent 9. Therefore, CO ₂ can be efficiently adsorbed without installing any special power for CO ₂ adsorption.

For example, as shown in FIG. 2, the CO ₂ adsorbent 10 is configured in the form of a pellet and stored in the storage bag 4.

Thereby, for example, the pellet-shaped CO ₂ adsorbent 10 can be collected while being kept in the storage bag 4. Although the shape of the pellet is not particularly limited, it may be, for example, cylindrical with a diameter of 5 mm and a length of 5 to 10 mm.

As shown in FIG. 1, a vending machine 1 is provided with a display means 5 for displaying the amount of CO ₂ adsorbed by a CO ₂ adsorbent. The display means 5 is, for example, a liquid crystal panel.

This makes it possible to make users of the vending machine 1 aware of the amount of CO ₂ adsorbed by the CO ₂ adsorbent, thereby promoting the fact that they are contributing to CO ₂ reduction and educating them about CO ₂ reduction. Can be done. In addition, vending machines can give consumers a positive image that they are contributing to greenhouse gas countermeasures, and vending machines have become a point of contact with all kinds of consumers, regardless of age or gender, and are being installed all over the country. As a result, it is expected that economies of scale will be utilized and a social movement such as ``introducing vending machines as a measure against greenhouse gases'' can be expected.

As shown in FIG. 3, the vending machine 1 includes a communication means 112 for transmitting or receiving the amount of CO _{2 adsorbed by the CO 2 adsorbent} via communication. The communication means 112 is, for example, a device that connects to the Internet to enable communication and send and receive various data. The communication means 112 can be provided as a function of the controller 100.

Thereby, the data on the amount of CO ₂ adsorption calculated by the calculation means 102 provided in the vending machine 1 can be transmitted to the outside, and the data can be used outside. Alternatively, data on the amount of CO ₂ adsorption calculated externally can be received and displayed on the display means 5, for example.

As shown in FIG. 2, the vending machine 1 is provided with an output means 114 for causing an external terminal to read the amount of CO ₂ adsorbed by the CO ₂ adsorbent. The output means 114 can be provided as a function of the controller 100.

As a result, for example, data on the amount of _CO2 adsorption can be obtained from an external terminal (handy terminal, etc.) of a route staff member who patrols the vending machine 1 and replenishes products, etc., and the data can be used externally. .

As shown in FIG. 2, the vending machine 1 includes a calculation means 102 for calculating the amount of CO ₂ adsorbed by the CO ₂ adsorbent. For example, the calculation means 102 can be provided as one function of the controller 100.

This allows the vending machine 1 to independently calculate the amount of CO ₂ adsorption.

As shown in FIG. 3, the amount of CO ₂ adsorption is calculated in the vending machine 1.
Calculation of CO ₂ adsorption amount is as follows:
obtaining adsorption factor data of a CO ₂ adsorbent installed in a vending machine;
The method includes a step of calculating the amount of CO ₂ adsorption.

By calculating in this way, by calculating the amount of CO ₂ adsorption based on the adsorption factor data, it is possible to obtain with high precision the amount of adsorption of CO ₂ according to the environment in which each vending machine is installed. can.

As shown in Figure 3,
The step of obtaining adsorption factor data is
Measuring means 120 provided in the vending machine,
a measuring means 220 located remote from the vending machine;
external data acquisition means 140 for acquiring external data;
This shall be carried out by at least one of the following: This may be done by a combination of a plurality of means.

As shown in Figure 3,
The measuring means 120 provided in the vending machine can be composed of a temperature measuring device, a humidity measuring device, a timer (a device for recording measurement time, etc.), and the like. The timer can be provided as a function of the controller 100, for example. In addition, the measuring means provided in the vending machine may be installed not only near the CO ₂ adsorbent inside the vending machine but also on the back external wall of the vending machine, etc., within the range where the present invention can be implemented. It is possible.

As shown in Figure 3,
The measuring means 220 located away from the vending machine includes a temperature measuring device, a humidity measuring device, and a timer (measurement time etc.). The adsorption factor data measured by the measuring means 220 located away from the vending machine can be transmitted to the vending machine or the management base 50 via the Internet 60.

As shown in Figure 3,
The external data acquisition means 140 that acquires external data is, for example, an external organization 230 (private organization or public organization) that provides weather data for the location where the vending machine is installed or the predetermined area where the vending machine is installed. ) is a means for acquiring temperature, humidity, and measurement time via the Internet 60. The external data acquisition means 140 can be provided as a function of the controller 100, for example.
Further, for example, temperature can be obtained from a measuring means provided in a vending machine, and humidity can be obtained from external data such as a local meteorological observatory and then calculated.

As shown in FIGS. 2 and 3,
The step of calculating the amount of _CO2 adsorption is
calculation means 102 provided in the vending machine;
a calculation means 202 installed at a location away from the vending machine;
This shall be carried out by at least one of the following. This may be done by a combination of a plurality of means.

The calculation means 202 located away from the vending machine may be located at a base (head office or branch office) that manages product replenishment for each vending machine installed in multiple locations, or at a predetermined area such as a specific administrative district. It can be provided as a function of a server 200 installed at a management base 50 such as a business office that manages sales.

As shown in Figure 3,
It is assumed that the adsorption factor data is at least one of temperature, humidity, and time. A plurality of them may be used.

The amount of CO ₂ adsorption (g) per unit weight (g) per unit time (h) using the adsorption factor data of temperature (environmental temperature) and humidity (environmental humidity) can be calculated using the following formula ( 1).
[Formula (1)]
CO ₂ adsorption amount (g) per unit weight (g) = 0.206 (g) + 0.283 (g) * Adsorbent coefficient + 0.0015 (g) * Environmental temperature + 0.0008 (g) * Environmental humidity Here The adsorbent coefficient is a constant predefined for each adsorbent.The environmental temperature is in degrees Celsius (°C), and the unit is dimensionless.
The environmental humidity is expressed as a percentage (%), and the unit is dimensionless.

For example, when 5 kg (5000 g) of CO ₂ adsorbent is installed in a vending machine, the amount of CO ₂ adsorbed (g) in one hour by the vending machine is calculated using the following formula (2). Desired.
[Formula (2)]
CO ₂ adsorption amount (g) = 5000 * {0.206 (g) + 0.283 (g) * Adsorbent coefficient + 0.0015 (g) * Environmental temperature + 0.0008 (g) * Environmental humidity}
Here, for the environmental temperature and the environmental humidity, for example, average values for the one hour can be used.
The one hour period used in the calculation can be measured by a vending machine or an external timer (device for recording measurement time, etc.).

In Figure 2, the _CO2 adsorbent is recovered after adsorbing _CO2 . The collection time is determined, for example, by the following method.
That is,
A method for determining the collection timing of a CO ₂ adsorbent in a vending machine equipped with a CO ₂ adsorbent, the method comprising:
obtaining adsorption factor data;
It is assumed that the method includes a step of determining the collection timing of the CO ₂ adsorbent.

According to this, by calculating the adsorption amount of CO ₂ based on adsorption factor data and determining the collection time of the CO ₂ adsorbent, the adsorption amount of CO ₂ is determined according to the environment in which each vending machine is installed. The collection timing is optimized based on the CO 2 adsorbent, and the CO ₂ adsorbent can be used without wasting it. For example, if the collection time is set too early, the CO ₂ adsorbent that could normally absorb more CO ₂ will be wasted, but the collection time can be set depending on the installation environment of the vending machine. Optimization can reduce this waste.

Also, as shown in Figure 3,
The step of deciding when to collect the CO ₂ adsorbent is
calculation means 104 provided in the vending machine;
a calculation means 202 installed at a location away from the vending machine;
This shall be carried out by at least one of the following. This may be done by a combination of a plurality of means.

Also, as shown in Figure 4,
The step of deciding when to collect the CO ₂ adsorbent is
The calculated CO ₂ adsorption amount,
This is done by comparing the adsorption standard amount of CO ₂ adsorbent.

For example, the calculation means 104 of the vending machine 1 stores an adsorption reference amount K (g) based on the weight of the installed CO ₂ adsorbent and the adsorbent coefficient (see equation 1).
This adsorption reference amount K (g) corresponds to the amount (g) of CO ₂ that can be adsorbed by the installed CO ₂ adsorbent. The adsorption reference amount K (g) is most preferably set to the amount of CO ₂ adsorption when the CO ₂ adsorbent reaches a saturated state where it cannot adsorb any more CO ₂ , that is, the saturated adsorption amount. In addition, for example, a CO ₂ adsorption amount that is 90% or 80% of the saturated adsorption amount may be set as the adsorption reference amount K (g).

FIG. 5 shows an example in which the adsorption reference amount is set to the saturated adsorption amount (the amount of CO ₂ adsorption when the CO ₂ adsorbent reaches a saturated state where it cannot adsorb any more CO ₂ ).
As shown in FIG. 5, the calculation means 104 monitors the integrated value M(g) (the cumulative value of the sum) of the CO ₂ adsorption amount (g) determined by equation (2), and monitors the adsorption reference amount K( In comparison with g), for example, when the integrated value M(g) reaches 80% of the adsorption reference amount K(g) (time T1), the collection time (time T2) is determined to be 10 hours later.

The above-mentioned determination of the collection time (time T2) may be performed by the calculation means 202 installed at a location away from the vending machine instead of the calculation means 104. The calculation means 104 and the calculation means 202 function as means for comparing the amount of CO ₂ adsorption with the adsorption reference amount and determining the collection time of the CO ₂ adsorbent.

As shown in Figure 4,
The method includes a step of outputting an alert signal when the amount of CO ₂ adsorption exceeds the adsorption reference amount (time T2). This alert signal serves as a flag to notify that the CO ₂ adsorbent has adsorbed a certain amount of CO ₂ and the time for recovery (time for replacement) of the CO ₂ adsorbent has arrived.

For example, the calculation means 104 outputs an alert signal when time T2 is reached. Further, the alert signal is output to, for example, the display means 5, and the display means 5 displays that the CO ₂ adsorbent needs to be recovered. In this case, the calculation means 104 functions as means for outputting an alert signal when the CO ₂ adsorbent exceeds the adsorption reference amount.

Further, the alert signal is read by the route staff's external terminal through the output means 114, for example, to notify the route staff that the CO ₂ adsorbent needs to be collected. Route staff can perform exchanges such as collecting CO ₂ sorbents and installing new CO ₂ sorbents.

Further, the alert signal is transmitted by the communication means 112 to, for example, the management base 50 located away from the vending machine, and the management base 50 recognizes that the CO ₂ adsorbent needs to be collected. The management base 50 can request the route staff to collect or replace the CO ₂ adsorbent.

FIG. 6 is a diagram illustrating an example of operation when CO ₂ is adsorbed by a plurality of vending machines 1. For example, several dozen vending machines 1 are installed in a specific administrative district (XX block, address, etc.). In the city, the vending machines 1 are installed everywhere, and can adsorb CO ₂ at each installation location, making it possible to contribute to reducing CO ₂ in the atmosphere over a wide range.

Route staff 70 patrols each vending machine 1 and replenishes products. For example, the route staff 70 checks the amount of CO ₂ adsorption displayed on the display means 5 of the vending machine 1 when replenishing products and the display indicating that collection is required, and at that time checks the CO ₂ Collect or exchange. Alternatively, the route staff 70 collects or replaces the CO ₂ adsorbent based on a notification to an external terminal that they carry. Alternatively, the route staff 70 collects or replaces the CO ₂ adsorbent based on a request from the management base 50.

For example, the CO ₂ adsorption amount calculated by the calculation means of each vending machine 1 is transmitted to the management base 50 via the Internet 60. As shown in FIG. 4, the management base 50 transmits an alert signal to the route staff 70 when time T2 is reached, requesting recovery or replacement of the CO ₂ adsorbent.

At the management base 50, the CO ₂ adsorption amount of each vending machine 1 is calculated by the calculation means of the management base 50 based on the adsorption factor data acquired through the Internet 60, for example. As shown in FIG. 4, the management base 50 transmits an alert signal to the route staff 70 when time T2 is reached, requesting recovery or replacement of the CO ₂ adsorbent.

At the management base 50, the CO ₂ adsorption amount of each vending machine 1 can be grasped. This makes it possible to consider, for example, adjusting the amount of CO ₂ adsorbent installed in each vending machine and optimizing the recovery schedule. It is also possible to analyze the installation environment (temperature, humidity) of the vending machine, and consider selecting the type of CO ₂ adsorbent to be used.

The management base 50 may perform a step of integrating the CO ₂ adsorbed by each vending machine 1 to calculate the total amount of CO ₂ adsorption.

This makes it possible to determine the total amount of _CO2 adsorbed by each vending machine 1 in a specific administrative district (○-chome, ○ address, etc.), and makes it possible to contribute to society with the total amount. It can help raise awareness of _CO2 reduction activities.

The composition of the CO ₂ adsorbent is not particularly limited.
For example, CO ₂ adsorbents include commercially available zeolites and activated carbon.
In addition, for example, the commercially available crystalline zeolite "Molecular Sieve 13X" has been disclosed as a CO ₂ recovery system for engines ("CO ₂ separation and recovery technology for engines using zeolite, Society of Automotive Engineers of Japan Transactions Vol. 53, No. 3, May 2022 ), and such crystalline zeolites (aluminosilicate crystalline materials) can also be used.

Alternatively, the CO ₂ adsorbent is made of something that can be reused by peeling off the CO ₂ that has been adsorbed once. Commercially available zeolite and activated carbon are available.

Moreover, the CO ₂ adsorbent is not limited to the pellet shape, and may be, for example, powder, sand, granule, block, filter, honeycomb structure, etc. In _addition , there are cases in which CO ₂ is fixed to the adsorbent through a chemical reaction, and cases in which CO ₂ is physically fixed to the adsorbent. Further, if the adsorbent can be installed in a liquid-filled cartridge or the like, the adsorbent may be a liquid such as potassium hydroxide or amines.

As shown in FIG. 6, the CO ₂ adsorbent collected by the route staff is collected at a management base 50, for example, and then subjected to a regeneration process before being installed in the vending machine again. By making the CO ₂ adsorbent reusable, it becomes possible to recycle it and prevent the environmental burden associated with disposal. Note that a known method can be used as the regeneration process (e.g., "Bench scale test of CO ₂ recovery from wet gas using a fixed bed of K2CO3-supported activated carbon", Journal of Chemical Engineering, Vol. 30, No. 5, 2004).・P668-P672).

FIG. 7 shows an embodiment of the vending machine 1. As shown in FIG.
The casing 6 of the vending machine 1 includes a bottom plate 6a, a side plate 6b, a back plate 6c, and a top plate 6d, and the front side of the casing 6 is configured to be closed or opened by the door 2. be done.

The casing 6 includes an interior space 21 for storing products 22 and cooling, heating, and keeping them warm, and a heat exchanger 32 located below the interior space 21 for discharging heat and/or discharging heat. and a storage space 31 for accommodating the storage space (having the function of absorbing heat) and the like.

The internal space 21 is surrounded by a heat insulating material 23. The storage space 31 is surrounded by the heat insulating material 23, the door 2, the bottom plate 6a, the side plate 6b, the back plate 6c, and the top plate 6d, which are arranged at the bottom of the internal space 21. In this example, the top surface of the housing space 31 is formed by the heat insulating material 23, but the top surface of the accommodation space 31 is not formed by the heat insulating material 23, but may be a plate material or the like. In the example of FIG. 7, the inside of the refrigerator is cooled or heated using the principle of a heat pump.

Moreover, a heat exchanger 26 and an internal fan 25 are provided in the internal space 21 . In addition, when a cooling chamber for cooling and a heating chamber for heating are formed in the internal space 21, a heat exchanger 26 and an internal fan 25 are installed in the cooling chamber and the heating chamber, respectively. will be provided.

In the housing space 31, a heat exchanger 32, a fan 33, a capillary tube 34 (an expansion valve may be used), and a compressor 35 are shown. For example, when cooling the inside of the cooling chamber of the internal space 21, the refrigerant flowing through the refrigerant pipe is compressed into high-pressure gas by the compressor 35 and becomes high temperature, thereby facilitating heat exchange. The refrigerant is then sent to a heat exchanger 32 (which in this case functions as a condenser). In the heat exchanger 32, the heat of the refrigerant is released by the outside air taken in from the outside of the vending machine 1 by the fan 33 to cool the refrigerant, and the refrigerant is liquefied. The pressure of the liquefied refrigerant is lowered in the capillary tube 34, making it easy to vaporize (evaporate), and then sent to the heat exchanger 24 (functioning as an evaporator in this case), where it is heated to a low temperature and low pressure state. When the refrigerant evaporates in the heat exchanger 24, it absorbs heat from the surrounding air, the surrounding air is cooled, and the cooled air is circulated in the internal space 21 by the internal fan 25. Through this circulation of cooling air, the temperature of the interior space 21 is lowered, and the products 22 are cooled and kept warm to a predetermined temperature.

Note that when heating the inside of the heating chamber in the internal space 21, heat is absorbed in the heat exchanger 32 using the principle of a heat pump, and high-temperature refrigerant is transferred from the compressor 35 to the heat exchanger 26. The inside of the refrigerator is heated using the supplied heat and released from the heat exchanger 26.

The accommodation space 31 communicates with an inlet where outside air flows in and an outlet where outside air is discharged. In one embodiment, the inlet through which outside air flows is configured as a vent 9 formed at the bottom of the door 2 . Further, in one embodiment, the inlet through which outside air is discharged is configured as a vent 91 formed at the lower part of the back plate 6c of the casing 6. As the fan 33 rotates, outside air is drawn into the housing space 31 through the ventilation hole 9, heat is exchanged between the outside air and the refrigerant in the heat exchanger 32, and the outside air that has absorbed heat is transferred to the outside of the housing space 31 through the ventilation hole 91. is discharged.

Note that the "lower part" such as the lower part of the door 2, the lower part of the back plate 6c, the lower part of the housing 6, etc. refers to, for example, the lowest position in the overall height in the vertical direction when the vending machine 1 is installed. Range from to 1/3 height, range to 1/4 height, range to 1/5 height, range to 1/6 height, range to 1/7 height, is exemplified.

In addition to a vending machine in which the internal space 21 is arranged on the upper side and the storage space 31 is formed below as in the configuration shown in FIG. It is also possible that

In the above configuration, for example, the CO ₂ adsorbent is installed outside the vending machine and installed at a location that comes into contact with the outside air taken into the inside of the vending machine. Specifically, for example, it is position A in FIG. 7, which is a position close to the vent 9, a position that closes the vent 9, etc. In this example, the CO 2 adsorbent can absorb CO ₂ contained in the outside air by contacting the CO ₂ adsorbent with the outside air before it is taken into the accommodation space 31 by _the rotation of the fan 33 .

In the above configuration, for example, the CO ₂ adsorbent is installed inside the vending machine and installed at a location that comes into contact with the outside air taken into the inside of the vending machine. Specifically, for example, at positions B to _D or position F in FIG _. Can be absorbed by materials.

In the above configuration, for example, the CO ₂ adsorbent is installed inside the vending machine, and is installed at a location that comes into contact with air released from the inside of the vending machine to the outside. Specifically, for example, it is position D in FIG. 7, which may be a position close to the vent 91, a position that blocks the vent 91, or the like. In this example, CO ₂ contained in the air that is being exhausted from the accommodation space 31 to the outside can be absorbed by the CO ₂ adsorbent.

In the above configuration, for example, it is assumed that the CO ₂ adsorbent is installed outside the vending machine and installed at a location in contact with air released from the inside of the vending machine to the outside. Specifically, for example, it is position E in FIG. 7, which may be a position close to the vent 91, a position that closes the vent 91, or the like. In this example, CO ₂ contained in the air exhausted from the accommodation space 31 to the outside can be absorbed by the CO ₂ adsorbent.

In the above configuration, for example,
The vending machine includes a heat exchanger 32 through which a refrigerant is passed;
A fan 33 for taking in outside air,
a compressor 35 for compressing refrigerant;
It has a housing space 31 that accommodates a heat exchanger 32, a fan 33, and a compressor 35,
The housing space 31 communicates with an inlet (vent 9) through which outside air flows in and an outlet (vent 91) through which outside air is discharged.
CO ₂ adsorbent is
Inside the housing space 31, a location between the inlet (vent 9) and the heat exchanger 32 (position A), a location between the heat exchanger 32 and the fan 33 (position F), a location between the fan 33 and the compression The compressor 35 is installed at at least one of the locations between the compressor 35 (position C) and the location between the compressor 35 and the outlet (vent 91) (position D). Thereby, CO ₂ contained in the outside air taken into the accommodation space 31 and the air remaining in the accommodation space 31 can be absorbed by the CO ₂ adsorbent.

In the above configuration, for example, as shown in FIGS. 8(A) to 8(C),
The CO ₂ adsorbent is provided outside the casing 6 of the vending machine 1 on at least one of the top plate 6d, side plate 6b, and back plate 6c that constitute the casing 6.
Specifically, as shown in each figure, for example, by installing a storage box 3 and accommodating a CO ₂ adsorbent 10 therein, CO ₂ contained in the air outside the vending machine 1 is removed. It is intended to adsorb. Note that by providing the storage box 3 with a fan for sucking outside air, adsorption of CO ₂ by the CO ₂ adsorbent 10 inside the storage box 3 may be promoted. In addition to the electric power for operating the vending machine 1, the driving force for the fan may be secured by a solar panel (not shown).
According to this example, the CO ₂ adsorbent can be retrofitted not only to a newly installed vending machine 1 but also to an existing vending machine 1.

1 Vending machine 2 Door 3 Containment box 4 Containment bag 5 Display means 6 Case 7 Takeout port 9 Ventilation port 10 CO ₂ adsorbent 50 Management base 60 Internet 70 Route staff 100 Controller 102 Calculation means 104 Calculation means 112 Communication means 114 Output Means 120 Measuring means 140 External data acquisition means 200 Server 202 Calculating means 220 Measuring means 230 External engine K Adsorption reference amount M Integrated value

Claims (20)

Vending machine equipped with CO ₂ adsorbent. The CO ₂ adsorbent is provided in a space of the vending machine where outside air is taken in.
The vending machine according to claim 1, characterized in that: The CO ₂ adsorbent is provided in a space at the bottom of the vending machine where outside air is taken in.
The vending machine according to claim 2, characterized in that: The CO ₂ adsorbent is provided on a door that is opened when filling a vending machine with products.
The vending machine according to claim 3, characterized in that: The CO ₂ adsorbent is provided at the bottom of the door.
The vending machine according to claim 4, characterized in that: The CO ₂ adsorbent is stored in a storage box provided at the bottom of the door.
The vending machine according to claim 5, characterized in that: The storage box is made of a net member.
The vending machine according to claim 6, characterized in that: The CO ₂ adsorbent is housed in a CO ₂ permeable storage bag.
The vending machine according to any one of claims 1 to 7. comprising a display means for displaying the amount of CO ₂ adsorbed by the CO ₂ adsorbent;
The vending machine according to any one of claims 1 to 7, characterized in that: comprising communication means for transmitting or receiving the amount of CO ₂ adsorbed by the CO ₂ adsorbent via communication;
The vending machine according to any one of claims 1 to 7, characterized in that: comprising an output means for causing an external terminal to read the amount of CO ₂ adsorbed by the CO ₂ adsorbent;
The vending machine according to any one of claims 1 to 7, characterized in that: comprising a calculating means for calculating the amount of CO ₂ adsorbed by the CO ₂ adsorbent;
The vending machine according to any one of claims 1 to 7, characterized in that: The CO ₂ adsorbent is installed outside the vending machine and at a location that comes into contact with the outside air taken into the vending machine.
The vending machine according to claim 1, characterized in that: The CO ₂ adsorbent is installed inside the vending machine, and installed at a location that comes into contact with the outside air taken into the vending machine.
The vending machine according to claim 1, characterized in that: The CO ₂ adsorbent is installed inside the vending machine and installed at a location that comes into contact with the air released from the inside of the vending machine to the outside.
The vending machine according to claim 1, characterized in that: The CO ₂ adsorbent is installed outside the vending machine and in a location that is in contact with the air released from the inside of the vending machine to the outside.
The vending machine according to claim 1, characterized in that: A vending machine has a heat exchanger through which refrigerant is passed,
A fan to bring in outside air,
a compressor for compressing refrigerant;
It has an accommodation space that accommodates a heat exchanger, a fan, and a compressor,
The accommodation space communicates with an inlet where outside air flows in and an outlet where outside air is discharged,
CO ₂ adsorbent is
Inside the accommodation space, at least a location between the inlet and the heat exchanger, a location between the heat exchanger and the fan, a location between the fan and the compressor, and a location between the compressor and the outlet. installed at one location,
The vending machine according to claim 1, characterized in that: The CO ₂ adsorbent is provided outside the casing of the vending machine on at least one of the top plate, side plate, and back plate that constitute the casing.
The vending machine according to claim 1, characterized in that: 7. The vending machine according to claim 6, wherein the storage box is made of a gas permeable material. 7. The vending machine according to claim 6, wherein the storage box is made of paper material.