CN221115260U - Storage box based on box cover detection - Google Patents

Abstract

The utility model discloses a storage box based on box cover detection, and relates to the technical field of disinfection storage. Including the box body, set up in the lid of box body opening part and set up in the accomodate the chamber in the box body, still include: the proximity sensing unit is used for detecting whether an object is contained in the containing cavity or not and outputting a containing signal when the object is contained in the containing cavity; the box cover detection unit is used for detecting the closing state of the box cover; and outputting a closing signal when the box cover is closed on the box body; a sterilizing unit for sterilizing the instrument received in the receiving chamber; and the main control unit triggers the disinfection unit to work when receiving the storage signal and the cover signal. The utility model solves the technical problems of single detection means and false triggering of disinfection work in the prior art.

Description

Storage box based on box cover detection

Technical Field

The utility model relates to the technical field of storage boxes, in particular to a storage box based on box cover detection.

Background

In the medical and cosmetic industries, various instruments are used, and the instruments need to be sterilized at random in the use process so as to prevent bacteria and viruses from breeding.

In the prior art, an instrument to be sterilized is usually put into a storage box, the storage box automatically detects the put state of the instrument, and when the instrument is determined to be put into the storage box, the sterilization work is started.

However, the existing disinfection opening mode has the problem that disinfection elements are easy to overflow. Therefore, how to provide a storage box capable of reducing the overflow of the sterilizing element is one of the difficulties to be solved.

Disclosure of utility model

In order to solve at least one technical problem mentioned in the background art, an object of the present utility model is to provide a storage box based on box cover detection and a working method thereof, which can more accurately detect the state of an object placed in the storage box and perform disinfection; false triggering can also be prevented and interference of external environment can be avoided.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

The utility model provides a receiver based on lid detects, includes the box body, sets up in the lid of box body opening part and sets up the receiving cavity in the box body, still includes:

The proximity sensing unit is used for detecting whether an object is contained in the containing cavity or not and outputting a containing signal when the object is contained in the containing cavity;

The box cover detection unit is used for detecting the closing state of the box cover; and outputting a closing signal when the box cover is closed on the box body;

A sterilizing unit for sterilizing the object received in the receiving chamber;

The main control unit is connected with the proximity sensing unit, the box cover detection unit and the disinfection unit, and triggers the disinfection unit when receiving the storage signal and the cover signal.

In some embodiments of the present utility model, the proximity sensing unit includes a transmitting end and a receiving end disposed on an inner wall of the receiving cavity; the sending end is used for sending an infrared signal, when the object is received in the receiving cavity, the infrared signal is reflected to the receiving end on the surface of the object, and the receiving end outputs the receiving signal.

In some embodiments of the present utility model, the cartridge cover detection unit includes a first hall element and a first magnet; one of the first Hall element and the first magnet is arranged on the box body, and the other one is arranged on the box cover; when the box cover covers the storage box, the first Hall element and the first magnet are correspondingly arranged.

In some embodiments of the present utility model, a category detection unit for detecting a category of the object is further included, and the category detection unit is electrically connected with the main control unit.

In some embodiments of the present utility model, the class detection unit includes a second hall element disposed on the case for sensing a second magnet disposed on an object, the second hall element and the second magnet being disposed corresponding when the object provided with the second magnet is placed in the storage case.

In some embodiments of the present utility model, the device further comprises a charging unit for charging the object stored in the storage cavity, the charging unit is connected with the main control unit, and the main control unit triggers the disinfection unit and the charging unit when receiving the storage signal and the cover signal.

In some embodiments of the present utility model, the charging device further comprises an electric quantity detection unit for detecting the electric quantity of the object, wherein the electric quantity detection unit is connected with the main control unit, so as to control the main control unit to trigger or disconnect the charging unit.

In some embodiments of the utility model, the transmitting end and/or the receiving end of the proximity sensing unit are provided with an electrostatic protector.

In some embodiments of the present utility model, a filtering unit is disposed on the transmitting end and/or the receiving end of the proximity sensing unit.

In some embodiments of the utility model, the filter unit employs a filter capacitor.

Compared with the prior art, the utility model has the beneficial effects that:

The utility model combines the proximity sensing unit and the box cover detection unit to detect whether the instrument is placed in the storage box or not and the cover state of the box cover, and further to ensure that the disinfection work is triggered when the instrument is placed in the storage box and the box cover is covered. On one hand, the state of the instrument placed in the storage box can be detected more accurately, and false triggering is prevented; on the other hand, the instrument can be ensured to be in a relatively sealed environment in the process of disinfection, and the interference of the external environment is prevented.

In addition, the cover closing state of the box cover is monitored, so that disinfection work performed when incorrect equipment is put in can be prevented to a certain extent, the cover cannot be closed correctly due to the problem of the external dimension when some incorrect equipment is put in, and in such a case, even if the proximity sensing unit is triggered, disinfection or charging work can not be triggered, so that the detection precision is improved.

Drawings

Fig. 1 is a schematic view of the overall structure of the storage box of the present utility model.

Fig. 2 is a schematic view of a housing cavity according to the present utility model.

Fig. 3 is a block diagram of a control system according to a first embodiment of the present utility model.

Fig. 4 is a circuit diagram of a proximity sensor unit according to a first embodiment of the present utility model.

Fig. 5 is a circuit diagram of a box cover detection unit according to a first embodiment of the present utility model.

Fig. 6 is a block diagram of a control system according to a second embodiment of the present utility model.

Fig. 7 is a block diagram of a control system according to a third embodiment of the present utility model.

Fig. 8 is a circuit diagram of a class detection unit according to a third embodiment of the present utility model.

In the figure: 1. a storage box; 11. a case body; 12. a storage chamber; 13. a box cover; 2. an infrared proximity sensor; 3. an ultraviolet lamp; 4. a charging interface; 51. a first hall element; 52. a first magnet; 6. and a second Hall element.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely, and it is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Embodiment one:

Referring to fig. 1, the present embodiment provides a storage box 1 based on box cover detection, where the storage box 1 includes a box body 11, a box cover 13 disposed at an opening of the box body, and a storage cavity 12 disposed in the box body 11.

As shown in fig. 2 and 3, a sterilizing unit is provided in the housing chamber 12:

The disinfection unit is used for disinfecting objects (particularly instruments) stored in the storage cavity, in this embodiment, the disinfection unit adopts ultraviolet lamps 3 arranged at the bottom of the storage cavity 12, the number of the ultraviolet lamps 3 can be determined according to the situation, and in this embodiment, 3 ultraviolet lamps are arranged;

the instrument to be sterilized is placed in the accommodating cavity 12, so that the influence of the external environment is isolated, and the sterilization of the instrument is realized more safely.

It is understood that the sterilizing unit is not limited to the ultraviolet lamp, but may include an ozone generator, a sterilizing liquid supply unit, a heat generating unit, etc., without limitation.

In order to avoid ineffective power consumption caused by the fact that the sterilization is started when no object is contained, as shown in fig. 3, a proximity sensing unit is further arranged in the embodiment.

The proximity sensing unit is used for detecting whether an object is contained in the containing cavity or not; the proximity sensing unit comprises a sending end and a receiving end which are arranged on the inner wall of the storage cavity; the transmitting end is used for sending an infrared signal, when the instrument is received in the receiving cavity, the infrared signal is reflected to the receiving end on the surface of the instrument, and the receiving end outputs a receiving signal.

Referring to fig. 2, the proximity sensor unit employs an infrared proximity sensor 2, the infrared proximity sensor 2 is disposed in the accommodating cavity 12, specifically, disposed at an opening at the bottom or the side of the accommodating cavity 12, and the transmitting end and the receiving end of the infrared proximity sensor 2 are spaced apart from the inner wall of the accommodating cavity 12 by a predetermined distance. The setting of the prescribed distance satisfies the following condition: when the instrument is stored in the storage cavity 12, the infrared signal emitted by the transmitting end is reflected to the receiving end by the surface of the instrument; when no instrument is stored in the storage chamber 12, the infrared signal emitted from the transmitting end cannot be received by the receiving end.

Referring to fig. 4, the circuit structure of the proximity sensing unit is as follows:

The 1 st pin of the chip U2 of the infrared proximity sensor 2 is grounded, the 2 nd pin is connected to the power bus VMCU_3V3, and the 4 th pin is connected to the power bus VMCU_3V3 through a current limiting resistor R9. When the pin 2 receives the U0 level, the transmitting end outputs an infrared signal; when the receiving end receives the infrared signal, a 3 rd pin of the chip U2 outputs a level signal lower than U0 (set threshold value), and the level signal is sent to a main control Module (MCU) through a node P_Sk1_DFT; when the receiving end does not receive the infrared signal, the node P_Sk1_DFT outputs a U0 level signal to a main control Module (MCU). So that it can be judged whether or not there is an instrument in the housing chamber 12 by the level signal (i.e., the housing signal).

In other embodiments, the proximity sensor unit may use a hall element and a magnet.

It should be noted that, in this circuit, in order to enhance the electrostatic protection effect, an electrostatic protector is disposed on the transmitting end and/or the receiving end of the proximity sensing unit. Specifically, the electrostatic protector ESD3 is connected to the 2 nd pin of the chip U2, and/or the electrostatic protector ESD4 is connected to the 3 rd pin.

On the other hand, in order to effectively reduce the influence of the interference signal on the circuit, a filtering unit is arranged on the transmitting end and/or the receiving end of the proximity sensing unit. Specifically, the 2 nd pin of the chip U2 is connected to the filter capacitor C6, and/or the 3 rd pin is connected to the filter capacitor C5.

In order to further ensure the isolation effect of the instrument and the external environment in the disinfection process, the embodiment also detects whether the storage box 1 is covered by the box cover or not. Specifically, as shown in fig. 1 and 3, the present embodiment provides a cap 13 and a cap detecting unit.

The box cover 13 is arranged at the opening of the box body 11 and is used for covering the opening;

The box cover detection unit is used for detecting the closing state of the box cover and outputting a closing signal;

Referring to fig. 1, the cover detection unit includes a first hall element 51 and a first magnet 52; one of the first hall element 51 and the first magnet 52 is mounted on the case 11, and the other is mounted on the case cover 13. The relative positions of the first hall element 51 and the first magnet 52 change along with the change of the closing state of the box cover 13, and when the box cover is closed, the first hall element 51 and the first magnet 52 are correspondingly arranged. It should be understood that the "corresponding arrangement" is not limited to the arrangement in which the first hall element 51 is opposite to the first magnet 52, but includes the arrangement in which the first hall element 51 is offset, as long as the first hall element 51 can sense the first magnet 52 in the case cover state.

In order to facilitate signal transmission between the first hall element 51 and the main control unit, the first hall element 51 is mounted on the box 11, specifically, the upper edge of the box; and the first magnet 52 is mounted to the lower edge of the cover 13. When the lid 13 is in the closing state, the first hall element 51 and the first magnet 52 are as close as possible, so that the first hall element 51 can more accurately detect the magnetic field signal generated by the first magnet 52, output a low level, and accurately realize the detection of the closing state of the lid.

As shown in fig. 5, hall_out1 is a level signal output from the first HALL element 51. When the cover 13 is in an open state, the first HALL element 51 fails to detect the magnetic field signal or the magnetic field signal is weak, and hall_out1 outputs a high level; when the cover 13 is in the closed state, the first HALL element 51 detects the magnetic field signal generated by the first magnet 52, and hall_out1 outputs a low level. The MCU thus determines the closing state of the cap 13 through hall_out1.

It should be noted that, in other embodiments, the lid detection unit may be implemented by an infrared sensor.

The embodiment also provides a Main Control Unit (MCU) for receiving the storage signal and the cover signal, when the main control unit receives the storage signal and the cover signal, it is judged that an object is in the storage cavity 12, and when the box cover 13 covers the opening, the disinfection unit is triggered to work.

In the embodiment, the proximity sensing unit and the box cover detection unit are combined to detect whether an object is placed in the storage box and the cover closing state of the box cover, and to ensure that when the object is placed in the storage box and the box cover is closed, the disinfection work is triggered again, and the frequency of false triggering can be reduced by adopting double-signal triggering, for example, if no object is placed in the storage box, disinfection can not be started even in the cover closing state, so that unnecessary invalid power consumption is reduced, and in addition, if the object is placed in the storage box, disinfection can not be started even in the cover opening state, so that the optimal disinfection effect is ensured; on the other hand, the instrument can be ensured to be in a relatively sealed environment in the process of disinfection, so that the ultraviolet lamp light can be placed to overflow, and the interference of the external environment to the storage cavity is prevented.

In addition, the cover closing state of the box cover is monitored, disinfection work performed when non-target equipment is put in can be prevented to a certain extent, because the non-target equipment cannot be correctly closed due to the problem of the external dimension when the non-target equipment is put in, and under the condition, even if the proximity sensing unit is triggered, the disinfection work can not be triggered, so that the detection precision is improved.

The embodiment combines the detection of the placement of the instrument and the closing state of the box cover, and makes comprehensive judgment under the corresponding scene, so that the working principle of the embodiment is more clearly known to the person skilled in the art:

The embodiment provides a working method of a storage box based on box cover detection, which comprises the following steps:

S01, when the instrument is placed in the accommodating cavity, the proximity sensing unit outputs an accommodating signal;

S02, when the box cover covers the opening of the box body, the box cover detection unit outputs a cover signal;

S03, the main control unit receives the storage signal and the cover signal, and when judging that an instrument is arranged in the storage cavity 12 and the box cover 13 covers the opening, the main control unit triggers the disinfection unit to work so as to disinfect the instrument.

Embodiment two:

On the basis of the first embodiment, as shown in fig. 6, the storage case of the present embodiment is also capable of charging the instrument. The device comprises a charging unit, a charging interface 4, a main control unit and a control unit, wherein the charging unit is used for charging an instrument stored in a storage cavity, and particularly the charging interface 4 is arranged on the side wall of the storage cavity 12.

In one scenario, when the main control unit receives the storage signal and the cover signal, it determines that there is an instrument in the storage cavity 12 and the box cover 13 covers the opening, the disinfection unit and the charging unit are triggered to operate simultaneously.

Of course, in order to reduce unnecessary energy consumption waste, the charging device may further include an electric quantity detection unit for detecting electric quantity of the object, where the electric quantity detection unit is connected to the main control unit to control the main control unit to trigger or disconnect the charging unit, that is, when the electric quantity detection unit detects that the charging device is full of electricity, a corresponding full electric signal is given to the main control unit, and the charging unit will not charge the object at this time.

Embodiment III:

On the basis of the first embodiment, the storage case of the present embodiment is also capable of charging the instrument. In particular to a scenario in which the instrument comprises at least two charging modes. Specifically, the charging voltage of the instrument in the storage box 1 includes two or more types, and therefore, the present embodiment needs to perform the judgment of the type of the instrument before charging, so as to avoid the damage of the instrument or the storage box caused by the wrong charging voltage.

Specifically, the charging unit provides at least two charging modes, each of which provides a respective charging voltage for a corresponding class of instruments.

As shown in fig. 7, the device further includes a class detection unit for detecting a class of the device, and when the device is received in the receiving cavity, the class detection unit detects the class of the device and outputs an object class signal to the main control unit, and the main control unit triggers the corresponding charging mode to charge the device.

The class detection unit comprises a second Hall element arranged on the box body and used for sensing a second magnet arranged on an object, when the object provided with the second magnet is placed in the storage box, the second Hall element and the second magnet are correspondingly arranged, and the second Hall element acquires different class signals by sensing the second magnet on the object to generate different magnetic fluxes. It is understood that the "corresponding arrangement" is not limited to the arrangement mode in which the second hall element is opposite to the second magnet, but includes the arrangement mode in which the second hall element and the second magnet are offset, as long as the second hall element can sense the second magnet when the object configured with the second magnet is placed in the accommodating cavity. There may be various embodiments regarding the category detection unit, for example:

first kind: the box body comprises at least two second Hall elements, second magnets corresponding to the second Hall elements are arranged on different objects, and the second Hall elements are in one-to-one correspondence with the second magnets in each disinfection mode or charging mode, so that the mode is the most conventional pairing mode;

second, be provided with the second hall element on the box body, be provided with the second magnet of different magnetism on the different objects, under every charging mode, second hall element and the second magnet of different magnetism one-to-one. In this embodiment, the number of the hall elements can be only one or a small number, and only the magnetism of the second magnet needs to be changed, for example, the change of materials is realized, so that the number of the hall elements is saved, and meanwhile, the installation position of the magnet on the object is relatively fixed;

Third, be provided with the second magnet of position difference on the different objects, be provided with the second hall element that can respond to the second magnet magnetic flux of different positions on the box body, the second hall element is linear hall element. In this embodiment, the number of second hall elements is also usually one or a small number, since by one linear hall element, the second magnets from different positions can be induced, resulting in different magnetic fluxes;

Fourth kind: one of the classes of devices is not provided with a second magnet; for other types of devices, a second magnet corresponding to the second Hall element is configured on the different types; at least one second Hall element is arranged on the box body, and the second Hall element corresponds to the second magnet one by one in each disinfection mode or charging mode; compared with the first configuration method, the method can save one second Hall element and one second magnet on the basis of detecting the same number of types of devices.

Fifth: no second magnet is configured on one of the classes of devices; aiming at other types of equipment, second magnets with different magnetic intensities are configured on the equipment with different types, and the second magnets with different magnetic intensities are in one-to-one correspondence with different disinfection modes or charging modes; the box body is provided with a second Hall element which can induce different magnetic field strengths of the second magnet, and the second Hall element is a linear Hall element. When the equipment without the second magnet is positioned in the accommodating cavity, the magnetic field intensity detected by the second Hall element is 0, and the equipment can be distinguished from other types of equipment.

Sixth: the second magnet is not configured in one of the classes of devices; aiming at other types of equipment, second magnets with different positions are configured on the equipment with different types, and the second magnets with different positions are in one-to-one correspondence with different disinfection modes or charging modes; the box body is provided with a second Hall element which can sense the magnetic field intensity of the second magnet at different positions, and the second Hall element is a linear Hall element. Similarly, when the equipment without the second magnet is positioned in the accommodating cavity, the magnetic field intensity detected by the second Hall element is 0, and the equipment can be distinguished from other types of equipment.

In this embodiment, a first relatively conventional pairing method is adopted, specifically, as shown in fig. 8, the hall_out2 is a level signal output by the second HALL element 6. When the instrument is positioned outside the accommodating cavity 12, the corresponding second Hall element 6 cannot detect the magnetic field signal or the magnetic field signal is weak, and the HALL_OUT2 outputs a high level; when the instrument is positioned in the accommodating cavity 12, the corresponding second HALL element 6 detects the magnetic field signal generated by the second magnet, and the hall_out2 outputs a low level. The MCU determines the type of instrument located in the receiving cavity 12 by which second HALL element 6 outputs hall_out2, thereby providing a corresponding charging mode and realizing accurate charging.

The device also comprises an electric quantity detection unit for detecting the electric quantity of the object; the electric quantity detection unit is connected with the charging unit and the main control unit, and when an object is detected to be in full electric quantity, the main control unit controls the charging unit to stop charging, so that the instrument is prevented from being charged by the excessive electric quantity, and the instrument battery is prevented from being damaged.

In this embodiment, the placement of the instrument and the detection of the type of the charging mode of the instrument are combined, and comprehensive judgment is performed in the corresponding scene.

Taking two charging modes (5V charging voltage, 12V charging voltage) as an example,

Mode one: two second hall elements 6 are configured for the two charging voltages; the two second hall elements 6 are arranged at different positions of the accommodating chamber 12; and a second magnet is provided at a position corresponding to the second hall element 6 for each instrument of the charging voltage. That is, the installation position of the second magnet in the 5V charging voltage instrument should be satisfied, and when the 5V charging voltage instrument is located in the receiving cavity 12, only the second hall element 6 corresponding to the 5V charging voltage can detect the expiration magnetic field signal; for a 12V charging voltage instrument, vice versa.

It is worth mentioning that in order to avoid that two second hall elements 6 detect the magnetic field signal of the same second magnet, the distance between the two second hall elements 6 should be as far as possible.

In this way, the type of instrument located in the housing chamber 12 can be determined by the level signals (object type signals) of the hall_out2 output from the two second HALL elements 6.

Mode two: for one of the 5V charging voltage and the 12V charging voltage, the second hall element is not configured (the corresponding device does not need to be configured with the second magnet), the other one is configured with the second hall element 6, and the corresponding device is configured with the second magnet. The mounting position of the second magnet in the instrument is as described above and will not be described in detail here.

In this way, the type of the instrument located in the housing chamber 12 can be judged by the level signal (object type signal) of hall_out2 output from the second HALL element 6 as well, and the installation of the magnet in one HALL element and the instrument in the corresponding charging mode can be reduced, thereby saving the cost.

When the number of charging modes is increased, it is only necessary to further increase the second hall element 6 and install the second magnet at the corresponding position in the instrument corresponding to the charging mode on the basis of the above first and second modes.

In addition, the power supply of the case 11 includes four modes as follows:

Mode one: the input voltage of the box body is 12V, and two paths of output are provided.

One path of the power supply circuit outputs 12V charging voltage, and when the corresponding charging mode is detected to be 12V charging voltage, the power supply circuit supplies power;

The other output is used for converting the 12V input voltage into 5V charging voltage through the voltage reduction circuit, and when the corresponding charging mode is detected to be 5V charging voltage, the circuit is used for supplying power.

Mode two: the input voltage of the box body is 5V, and two paths of output are provided.

One path of the output is 5V charging voltage, and when the corresponding charging mode is detected to be 5V charging voltage, the path supplies power;

The other output is used for converting the 5V input voltage into 12V charging voltage through the booster circuit, and when the corresponding charging mode is detected to be the 12V charging voltage, the circuit is used for supplying power;

Mode three: the input voltage of the box body comprises 5V and 12V, and an adapter with a built-in quick-charging protocol chip is arranged on the box body; the adapter outputs a 5V charging voltage or a 12V charging voltage according to the object class signal. And according to the detected charging mode, the fast charging protocol chip in the adapter controls the corresponding input voltage and provides corresponding charging voltage for charging the instrument.

Mode four: in this way, each storage box only provides one charging mode, namely 5V or 12V charging voltage, when detecting that the placed instrument is matched with the charging mode, charging is carried out, otherwise, the storage box is not charged and abnormality is prompted.

The embodiment further combines the proximity sensing unit, the box cover detection unit and the class detection unit, and combines the detection of the instrument class on the basis of the first embodiment, so that a corresponding charging mode can be provided, and the storage box and/or the instrument are prevented from being damaged in the charging process due to mismatching of charging voltages.

The embodiment combines the instrument placement and the detection of instrument types in different charging modes, and makes comprehensive judgment in corresponding scenes, so that the working principle of the embodiment is more clearly known to the person skilled in the art:

The embodiment provides a working method of a storage box, which comprises the following steps:

S11, when the instrument is placed in the accommodating cavity, an infrared signal sent by a sending end of the proximity sensing unit is reflected to a receiving end on the surface of the instrument, and the receiving end outputs an accommodating signal;

S12, when the box cover covers the opening of the box body, the box cover detection unit outputs a cover signal;

S13, detecting the type of the instrument in the accommodating cavity by the type detection unit and outputting an object type signal;

And S14, when the main control unit receives the storage signal and the object type signal and judges that the storage cavity 12 is provided with an instrument and the charging mode type of the instrument is determined, the main control unit triggers the disinfection unit to disinfect the instrument and triggers the charging unit to provide a corresponding charging mode to charge the instrument.

Embodiments of triggering conditions for the disinfection unit and the charging unit are described in detail below.

1. The conditions for triggering the judgment of the sterilizing unit alone are shown in the following table 1;

table 1: trigger condition judgment table of single disinfection unit

2. Taking an example of an instrument with two charging modes of 5V charging voltage (second hall element is configured) and 12V charging voltage (second hall element is not configured), the conditions for comprehensively triggering the judgment of the sterilizing unit and the charging unit are as follows in table 2:

table 2: trigger condition judgment table for integrated disinfection unit and charging unit

Embodiment four:

Based on the class detection unit in the third embodiment, the class detection unit may also be used to perform different disinfection modes, and in another embodiment of the present utility model, the disinfection unit may also provide different disinfection modes, so that after the class detection unit recognizes objects of different classes, the class detection unit may trigger corresponding disinfection modes, so-called different disinfection modes may be classified into different disinfection times, different disinfection powers, and so on.

The specific implementation of the category detection unit has been specifically developed in the third embodiment, which is not described in any more detail.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims (10)

1. The utility model provides a receiver based on lid detects, includes the box body, sets up in the lid of box body opening part and sets up the receiving cavity in the box body, its characterized in that, still including setting up in the box body:

The proximity sensing unit is used for detecting whether an object is contained in the containing cavity or not and outputting a containing signal when the object is contained in the containing cavity;

The box cover detection unit is used for detecting the closing state of the box cover; and outputting a closing signal when the box cover is closed on the box body;

A sterilizing unit for sterilizing the object received in the receiving chamber;

The main control unit is connected with the proximity sensing unit, the box cover detection unit and the disinfection unit, and triggers the disinfection unit when receiving the storage signal and the cover signal.

2. The storage box based on box cover detection according to claim 1, wherein the proximity sensing unit comprises a sending end and a receiving end which are arranged on the inner wall of the storage cavity; the sending end is used for sending an infrared signal, when the object is received in the receiving cavity, the infrared signal is reflected to the receiving end on the surface of the object, and the receiving end outputs the receiving signal.

3. The case lid detection-based storage case according to claim 1, wherein the case lid detection unit includes a first hall element and a first magnet; one of the first Hall element and the first magnet is arranged on the box body, and the other one is arranged on the box cover; when the box cover covers the storage box, the first Hall element and the first magnet are correspondingly arranged.

4. The storage box based on box cover detection according to claim 1, further comprising a category detection unit for detecting the category of the object, wherein the category detection unit is electrically connected with the main control unit.

5. The case lid detection-based storage case according to claim 4, wherein the class detection unit includes a second hall element disposed on the case body for sensing a second magnet disposed on an object, the second hall element and the second magnet being disposed corresponding to each other when the object provided with the second magnet is placed in the storage case.

6. The case lid detection-based case of any one of claims 1 to 5, further comprising a charging unit for charging an object stored in the storage chamber, the charging unit being connected to the main control unit, the main control unit triggering the sterilizing unit and the charging unit upon receiving the storage signal and the lid signal.

7. The storage box based on box cover detection according to claim 6, further comprising an electric quantity detection unit for detecting electric quantity of an object, wherein the electric quantity detection unit is connected with the main control unit to control the main control unit to trigger or disconnect the charging unit.

8. The storage box based on box cover detection according to claim 2, wherein an electrostatic protector is arranged on a sending end and/or a receiving end of the proximity sensing unit.

9. The storage box based on box cover detection according to claim 2, wherein a filter unit is arranged on a sending end and/or a receiving end of the proximity sensing unit.

10. The storage box based on box cover detection according to claim 9, wherein the filtering unit adopts a filtering capacitor.