CN220822643U - Emergency rescue equipment and wireless charging system applied to same - Google Patents

Abstract

The utility model discloses emergency rescue equipment and a wireless charging system applied to the emergency rescue equipment, comprising a power module and a charging cabinet, wherein the power module is installed in the emergency rescue equipment, the charging cabinet is used for charging the power module, and the power module comprises a battery shell, a battery cell arranged in the battery shell and a receiving coil connected with the battery cell; the charging cabinet comprises a cabinet body used for placing the emergency rescue equipment, a transmitting coil arranged in the cabinet body, and a transmitting control module used for controlling the transmitting coil to provide energy for the receiving coil. Compared with the prior art, the wireless charging system provided by the utility model adopts a wireless charging mode to replace a dry battery in the traditional emergency rescue equipment, prolongs the service life of the battery of the emergency rescue equipment, and saves the cost.

Description

Emergency rescue equipment and wireless charging system applied to same

Technical Field

The utility model relates to the field of medical use, in particular to emergency rescue equipment and a wireless charging system applied to the emergency rescue equipment.

Background

Along with the rapid development of electronic technology, electronic products are various in variety and powerful in function. The demand for battery power is increasing, and various types of batteries are increasing, but the application in emergency rescue is less.

At present, emergency rescue equipment is usually arranged in public places such as railway stations, subway stations, communities, hospitals, parks and the like. When encountering a person needing rescue, the patient is taken out to rescue. Because the equipment is stored for too long (3-5 years), the electric quantity of the battery in the rescue product can be gradually consumed, and the rescue effect is affected.

If a traditional rechargeable battery is adopted, a wiring mode is needed, and the wiring mode is easy to be influenced by environmental factors in public places, so that the use of emergency rescue equipment is influenced.

Disclosure of utility model

Aiming at the problems that in the prior art, the service life of a battery in emergency rescue equipment is short and the treatment effect is affected, the utility model provides the emergency rescue equipment and a wireless charging system applied to the emergency rescue equipment.

The technical scheme of the utility model is that the wireless charging system applied to the emergency rescue equipment comprises a power module and a charging cabinet, wherein the power module is installed in the emergency rescue equipment, the charging cabinet is used for charging the power module, and the power module comprises a battery shell, an electric core arranged in the battery shell and a receiving coil connected with the electric core;

The charging cabinet comprises a cabinet body used for placing the emergency rescue equipment, a transmitting coil arranged in the cabinet body, and a transmitting control module used for controlling the transmitting coil to provide energy for the receiving coil.

Further, the battery housing includes a battery upper cover and a battery lower cover, the battery upper cover being disposed toward the charging cabinet;

The receiving coil is arranged on the inner side of the upper battery cover, at least one magnetic attraction device is arranged at the position matching part of the outer side of the upper battery cover and the receiving coil, and the magnetic attraction device can be adsorbed on the charging cabinet and enables the positions of the receiving coil and the transmitting coil to be matched.

Further, the power module further includes:

The wireless charging control module is arranged in the battery shell, connected with the receiving coil and used for controlling the receiving coil to receive the energy provided by the transmitting coil;

The battery cell protection module is arranged in the battery shell, is connected with the battery cell and is used for detecting working parameters of the battery cell and triggering charging protection;

And the charging management module is arranged in the battery shell, is connected between the wireless charging control module and the battery cell protection module and is used for adjusting the charging voltage and the discharging voltage of the battery cell.

Further, a plurality of power supply contacts for connecting with and supplying power to the emergency rescue equipment are arranged on the outer surface of the battery shell;

the charging management module is arranged at the position matched with the power supply contact in the battery shell, and the power supply contact is arranged on the charging management module.

Further, a battery shielding plate is arranged in the battery shell and positioned between the electric core and the receiving coil;

the battery shielding plate is used for isolating the magnetic field generated by the receiving coil.

Further, at least one waterproof vent hole which is communicated with the inside of the battery shell and the outside is also formed in the battery lower cover.

Further, a spring piece clamped with the emergency rescue equipment is further arranged on the battery lower cover, and when the spring piece is triggered, the power module can be peeled off from the emergency rescue equipment.

Further, the power module further comprises an adapter connected with the emission control module, wherein the adapter is used for an external alternating current power supply and converting alternating current provided by the alternating current power supply into direct current which can be used by the emission control module.

Further, the battery shell is made of plastic materials, and the battery upper cover and the battery lower cover are formed in a mode of pressing by an ultrasonic process.

The utility model also provides emergency rescue equipment, which is provided with the wireless charging system.

Compared with the prior art, the utility model has at least the following beneficial effects:

The utility model adopts a wireless charging mode to supply power to the power supply module, can ensure sufficient electric quantity of the power supply module in real time, and ensures the treatment effect of emergency rescue equipment. In addition, compared with the traditional mode of adopting a dry battery or a wired rechargeable battery, the utility model has longer endurance time, is not easy to be interfered by the outside, has longer service life and meets the use requirement of emergency rescue equipment.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic diagram of a wireless charging system according to a first embodiment of the present utility model;

fig. 2 is a schematic diagram of a wireless charging system according to a second embodiment of the present utility model;

FIG. 3 is an exploded view of the overall structure of the present utility model;

FIG. 4 is a schematic diagram of the power module according to the present utility model;

FIG. 5 is a schematic diagram of the charging cabinet according to the present utility model;

fig. 6 is a schematic view of the structure of a battery case according to the present utility model;

FIG. 7 is a workflow diagram of the present utility model;

FIG. 8 is the overall operating logic of the present utility model;

The emergency rescue equipment comprises a charging cabinet 1, emergency rescue equipment 2, a battery lower cover 100, a charging terminal 101, a charging management module 102, a battery core protection module 103, a battery shielding plate 104, a receiving coil 105, a battery upper cover 106, a magnetic attraction device 107, a battery core 108, a wireless charging control module 109, a transmitting coil 110, an adapter 111, a transmitting control module 112, a cabinet body 113 of the charging cabinet, an output port 10, waterproof ventilation holes 11 and a spring sheet 12.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Thus, reference throughout this specification to one feature will be used in order to describe one embodiment of the utility model, not to imply that each embodiment of the utility model must be in the proper motion. Furthermore, it should be noted that the present specification describes a number of features. Although certain features may be combined together to illustrate a possible system design, such features may be used in other combinations not explicitly described. Thus, unless otherwise indicated, the illustrated combinations are not intended to be limiting.

The principles and structures of the present utility model are described in detail below with reference to the drawings and the examples.

The existing emergency rescue equipment is often prepared in public places such as railway stations, subway stations, communities, hospitals, parks and the like. The internal battery of the emergency rescue equipment is often a dry battery which cannot be used continuously, and when the emergency rescue equipment is stored for too long, the emergency rescue equipment can be used for rescuing due to electricity consumption. In some scenes, the emergency rescue equipment adopts a wired rechargeable battery, and the mode can realize sustainable use, but the mode of wiring is adopted in public places, so that the emergency rescue equipment is easily influenced by environmental factors, and the service life of the emergency rescue equipment is influenced. The utility model provides a wireless charging system which charges a power module in a wireless charging mode, so that the problems are avoided, and the service life of the power module is prolonged.

Specifically, the wireless charging system provided by the utility model comprises a power module arranged in emergency rescue equipment and a charging cabinet for charging the power module;

The power module comprises a battery shell, a battery core 108 arranged in the battery shell and a receiving coil 105 connected with the battery core 108;

The charging cabinet 1 includes a cabinet 113 for placing emergency rescue equipment, a transmitting coil 110 provided in the cabinet 113, and a transmission control module 112 for controlling the transmitting coil 110 to supply power to the receiving coil 105.

As shown in fig. 1, 4 and 5, the charging cabinet 1 is L-shaped, and the emergency rescue apparatus 2 is placed on the charging cabinet 1 and is charged in a wireless manner. In particular use, the power module is installed in the emergency rescue device 2, the emergency rescue device 2 is placed on the cabinet 113 of the charging cabinet 1 and the receiving coil 105 is aligned with the transmitting coil 110, at which time the transmitting control module 112 is activated to energize the receiving coil 105 through the transmitting coil 110. After receiving the energy provided by the transmitting coil 110, the receiving coil 105 can convert the energy into electric energy and provide the electric energy to the battery cell 108, so as to charge the power supply module.

Compared with the traditional scheme, the scheme can realize sustainable use of the power module without wiring, is basically not interfered by environmental factors, and prolongs the service life of the power module in the emergency rescue equipment 2.

The shape of the charging cabinet 1 is not limited to L, and in other embodiments of the present utility model, the shape of the charging cabinet 1 may be square, rectangular, etc., and the fixing manner may be any one of wall-hanging, vertical, and wall-leaning, which is not limited in the present utility model.

In addition, the charging mode of the utility model has two implementation modes, one is a magnetic charging mode, as shown in fig. 1, a charging interface adopts a magnetic interface or a DC interface, one end of a power module is designed into a magnetic chuck, one end of a charging cabinet 1 is an adapter, and an output head of the adapter is a magnetic suction head. When the emergency rescue equipment 2 is placed on the charging cabinet 1, the output head of the adapter in the charging cabinet 1 can be attracted by the magnetic attraction type sucker on the battery to be charged.

Another implementation manner is a wireless charging mode, as shown in fig. 2, power is supplied through a transmitting module (including a transmitting coil) arranged in the charging cabinet 1, and the magnet is used for adsorbing during power supply, so that the alignment precision is ensured.

Referring to fig. 4, the battery housing of the present utility model includes a battery upper cover 106 and a battery lower cover 100, wherein the battery upper cover 106 is disposed towards the charging cabinet 1;

The receiving coil 105 is disposed on the inner side of the battery top cover 106, and at least one magnetic attraction device 107 is disposed on the outer side of the battery top cover 106 and at a position matching with the receiving coil 105, and the magnetic attraction device 107 can be attracted to the charging cabinet 1 and match the positions of the receiving coil 105 and the transmitting coil 110.

The magnetic attraction device 107 may be a magnet or a magnetic material, and the charging efficiency of the wireless charging system is related to the alignment of the receiving coil 105 and the transmitting coil 110. The magnetic attraction device 107 is adopted for alignment, so that the accuracy of alignment of the receiving coil 105 and the transmitting coil 110 can be ensured, and after the alignment, the alignment of the receiving coil 105 and the transmitting coil 110 is ensured not to deviate, thereby ensuring the charging efficiency of the charging cabinet 1 on the power supply module and meeting the charging requirement of the power supply module. The number of the magnetic attraction devices 107 is not limited, and may be 1, 2, 3, 4, or the like. As shown in fig. 5, in order to match the magnetic attraction device 107 on the power module, the magnetic attraction device 107 is correspondingly disposed on the cabinet 113 in the utility model, so as to further ensure the alignment of the receiving coil 105 and the transmitting coil 110.

Here, the magnetic attraction device 107 may be provided at a position where the inner side of the battery top cover 106 matches the position of the receiving coil 105, as long as the receiving coil 105 and the transmitting coil 110 can be aligned. The receiving coil 105 and the wireless charging control module 109 may be fixed on the inner side of the battery upper cover 106 by using a double-sided adhesive, and the receiving coil 105 receives the energy sent by the transmitting coil 110 to generate an induced current, thereby achieving the charging effect. Because the receiving coil 105 is fixed on the inner side of the battery upper cover 106 by adopting a double-sided adhesive bonding mode, in order to avoid electric leakage, the material of the battery shell needs to be made of a plastic material, so that the waterproof discharging requirement is met.

Referring to fig. 3 and 4, the power module according to the present utility model further includes:

A wireless charging control module 109, disposed in the battery case and connected to the receiving coil 105, for controlling the receiving coil 105 to receive the energy provided by the transmitting coil 110;

The battery cell protection module 103 is arranged in the battery shell, is connected with the battery cell 108, and is used for detecting the working parameters of the battery cell 108 and triggering charging protection;

The charging management module 102 is disposed in the battery case, and is connected between the wireless charging control module 109 and the battery protection module 102, for adjusting the charging voltage and the discharging voltage of the battery 108.

In operation, the wireless charging control module 109 can control the start and stop of the wireless charging operation to cut off the charging state. The cell protection module 103 is used for protecting the cell 108, and avoiding damage to the cell 108 caused by too high charging voltage. The charging management module 102 is configured to adjust a charging voltage and a discharging voltage, when the power module is charged, the charging management module 102 can convert the charging voltage obtained from the receiving coil 105 into a voltage that can be used by a power supply, and when the power module is discharged corresponding to the emergency protection device 2, the charging management module 103 can convert the discharging voltage output by the power supply 108 into a voltage that can be used by the emergency protection device 2.

Through the mutual coordination of the wireless charging control module 109, the battery cell protection module 103 and the charging management module 102, the free switching of the utility model in the charging mode and the power supply mode can be realized, and the actual use requirement is met. Here, the charging mode refers to charging the battery cell 108 through the charging cabinet 1, which is generally performed when the electric quantity of the battery cell 108 is low, and the power supply mode refers to supplying power to the emergency rescue device 2 by the battery cell 108, so as to ensure the normal operation of the emergency rescue device 2, wherein the DCDC module is integrated in the charging management module 102, so that the charging voltage and the discharging voltage can be adjusted to meet the charging requirement of the battery cell 108 and the power supply requirement of the emergency rescue device 2.

The charging management module 102 and the battery core protection module 103 are also integrated with power supply such as overcharge, overcurrent and short-circuit protection, and have functions of battery core equalization, electric quantity calculation, electric quantity indication, one-wire and the like, so that the real-time detection of the state of the battery core and abnormal protection are realized, and the safety of the utility model is greatly improved.

Further, in order to realize the power supply of the power module corresponding to the emergency rescue equipment 2, the utility model is provided with a plurality of power supply contacts 101 on the outer surface of the battery shell for connecting with and supplying power to the emergency rescue equipment 2;

The charging management module 102 is disposed in the battery case and is matched with the power supply contact, so that the power supply contact 101 is mounted on the charging management module.

As shown in fig. 1 and fig. 4, the power supply contact 101 is disposed on the battery housing, and the charging management module 102 may be disposed at a corresponding position on the inner side surface of the battery lower cover 100, so that the output end of the charging management module 102 is disposed at the power supply contact 101 and electrically connected to the power supply contact 101, thereby ensuring normal power supply of the power supply contact 101. Wherein the power supply contacts 101 are provided with a plurality to form the output port 10 for connection with emergency rescue equipment.

Referring to fig. 4, a battery shielding plate 104 is disposed in the battery case and between the battery cell 108 and the receiving coil 105;

The battery shield 104 serves to isolate the magnetic field generated by the receiving coil 105.

Specifically, the battery shielding plate 104 may be made of a metal material, and can focus the magnetic field generated by the receiving coil 105, and play a role in shielding, so as to avoid the influence of the magnetic field generated by the receiving coil 105 on the operation of the control chip on the battery core protecting plate 1102. The receiving coil 105 and the transmitting coil 110 provided in the present utility model may be formed by winding one or more coils, and the shape of each coil may be different, which may be adjusted according to actual needs.

Referring to fig. 6, at least one waterproof vent 11 communicating the inside of the battery case with the outside is further provided on the battery lower cover 100.

Here, the waterproof vent 11 is used for communicating the inside and the outside of the battery shell, so that the gas exchange between the battery shell and the outside is ensured, the heat exchange is ensured, and a series of heating problems caused by overhigh temperature in the battery shell are avoided.

Referring to fig. 6, a spring 12 is further provided on the battery lower cover 100 and is engaged with the emergency rescue device 2, and when the spring 12 is triggered, the power module can be peeled off the emergency rescue device 2.

Specifically, the elastic sheet 12 may be disposed on the battery lower cover 100 in a fastening and fixing manner, and the power module is fixed in the emergency rescue device 2 in this manner, and when the power module needs to be detached, the emergency rescue device 2 and the power module can be separated only by triggering the elastic sheet 12.

Referring to fig. 5, the power module according to the present utility model further includes an adapter 111 connected to the emission control module 112, where the adapter 111 is used for externally connecting an ac power source and converting ac power provided by the ac power source into dc power for the emission control module 112.

Specifically, the adapter 111 includes an AC/DC module that performs AC/DC conversion to convert AC power into DC power, thereby satisfying the use of the emission control module 112.

Further, since the receiving coil 105 is mounted on the upper cover 106 of the battery, in order to avoid the problems of leakage, water and the like, the battery housing is made of plastic material, and the upper cover and the lower cover of the battery are pressed together by ultrasonic technology to form the battery housing.

Based on the wireless charging system, the utility model also provides a control method of the wireless charging system, which comprises the following steps:

detecting the residual electric quantity of the power supply module;

Judging whether the residual electric quantity is lower than an electric quantity threshold value or not;

If yes, the pairing of the charging cabinet and the power module is executed, and after the pairing is completed, the charging action is executed.

In addition, during the charging process, the control method further includes:

and after the power supply module is charged, sending a stop instruction to the charging management module, and ending the charging.

Please refer to fig. 7, which is an overall workflow diagram of the present utility model, wherein the change of the remaining power of the power module is recorded in real time by the battery protection module 103, and then converted into a percentage form, and transmitted to the charging management module 102;

The charging management module 102 has an MCU, which determines whether the remaining power is lower than the preset power after receiving the information of the remaining power, if yes, starts charging, at this time, the charging management module 102 sends a charging instruction to the wireless charging control module 109, and the wireless charging control module 109 mates with the transmitting control module 111 (i.e. password verification pairing) after receiving the charging instruction, and starts charging after completing the pairing.

At this time, the charging management module 102 can control the charging voltage, perform constant voltage charging when the charging voltage is higher than the preset voltage, perform constant voltage charging after the charging voltage is higher than the preset voltage when the charging voltage is lower than the preset voltage, then stop charging after the remaining power of the power supply module is higher than the preset power, and return to the detection process of the battery cell protection module 103.

Specifically, the battery cell protection module 103 has an electricity meter IC therein, which can record the electricity of the battery cell 108 in real time, and store the electricity in the form of percentages in the IC. The charge management module 102 may communicate with the electricity meter IC at a frequency to query the percentage of battery charge. The charging management module 102 can determine whether the percentage of the battery core electric quantity is lower than the preset electric quantity, if yes, a charging instruction is sent to the wireless charging control module 109, the wireless charging control module 109 is paired with the transmitting control module 111 after receiving the charging instruction, and after pairing is completed, the transmitting control module 111 controls the transmitting coil 110 to provide energy for the receiving coil 105, so that charging action is executed. After the charging is completed, the charging management module 102 sends a stop command to the wireless charging control module 109, and after the wireless charging control module 109 receives the stop command, contacts the pairing with the transmitting control module 111 and stops charging.

The fuel gauge IC according to the present utility model is a separate fuel gauge chip, and is not limited to a brand, and the power threshold may be set to any value of 0 to 99%, preferably 15%. Pairing protocols of the wireless charging control module 109 and the transmission control module 111 include, but are not limited to, QI protocol, WPS protocol, privacy protocol, and the like.

Referring to fig. 8, which is an overall control scheme of the present utility model, when a battery cell is charged, the AC-DC adapter can convert external AC power into DC power and provide the DC power to the wireless control transmitting line (i.e., the transmitting control module 111), then the transmitting control module 111 controls the transmitting coil 110 to provide energy to the receiving coil 105, the receiving coil 105 receives the energy and converts the energy into electric energy and provides the electric energy to the wireless receiving control line (i.e., the wireless charging control module 109), then the wireless receiving control line supplies power to the charging management control line (i.e., the charging management module 102), the charging management control line supplies power to the battery cell protection line (i.e., the battery cell protection module 103), and then the battery cell protection line supplies power to the battery pack (i.e., the battery cell 108), so as to complete the charging operation. When power is supplied, the battery pack supplies power to the battery cell protection circuit and the charging pipeline control circuit in sequence, and then supplies power to the emergency rescue equipment through the output port 10.

The charge management control circuit is also connected with a power indicating lamp, which can display the power of the battery cell 108 in a bulb mode, so that a user can find and supply power in time.

The utility model also provides emergency rescue equipment, which is provided with the wireless charging system.

Compared with the prior art, the wireless power supply device adopts a wireless charging mode to supply power to the power supply module, so that the sufficient electric quantity of the power supply module can be ensured in real time, and the treatment effect of emergency rescue equipment is ensured. In addition, compared with the traditional mode of adopting a dry battery or a wired rechargeable battery, the utility model has longer endurance time, is not easy to be interfered by the outside, has longer service life and meets the use requirement of emergency rescue equipment.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (9)

1. The wireless charging system for the emergency rescue equipment comprises a power module and a charging cabinet, wherein the power module is installed in the emergency rescue equipment, and the charging cabinet is used for charging the power module;

The charging cabinet comprises a cabinet body used for placing the emergency rescue equipment, a transmitting coil arranged in the cabinet body, and a transmitting control module used for controlling the transmitting coil to provide energy for the receiving coil;

The battery shell comprises a battery upper cover and a battery lower cover, and the battery upper cover is arranged towards the charging cabinet;

The receiving coil is arranged at the inner side of the battery upper cover and is arranged at the outer side of the battery upper cover and the receiving coil

The coil position matching department is provided with at least one magnetism and inhales the device, magnetism inhale the device can adsorb on the rack that charges, and make receiving coil with transmitting coil's position matching.

2. The wireless charging system of claim 1, wherein the power module further comprises:

The wireless charging control module is arranged in the battery shell and connected with the receiving coil for use in the battery

Controlling the receiving coil to receive the energy provided by the transmitting coil;

The battery cell protection module is arranged in the battery shell, is connected with the battery cell and is used for detecting working parameters of the battery cell and triggering charging protection;

And the charging management module is arranged in the battery shell, is connected between the wireless charging control module and the battery cell protection module and is used for adjusting the charging voltage and the discharging voltage of the battery cell.

3. The wireless charging system of claim 2, wherein a plurality of power supply contacts are provided on an exterior surface of the battery housing for connecting to and supplying power to the emergency rescue apparatus;

the charging management module is arranged at the position matched with the power supply contact in the battery shell, and the power supply contact is arranged on the charging management module.

4. The wireless charging system of claim 1, wherein a battery shield is disposed within the battery housing between the battery cell and the receiver coil;

the battery shielding plate is used for isolating the magnetic field generated by the receiving coil.

5. The wireless charging system of claim 1, wherein the battery is covered on the lower cover

At least one waterproof vent hole is also arranged for communicating the inside of the battery shell with the outside.

6. The wireless charging system of claim 1, wherein a spring tab is further provided on the battery lower cover for engaging the emergency rescue device, and the power module is configured to release the emergency rescue device when the spring tab is triggered.

7. The wireless charging system of claim 1, wherein the power module further comprises an adapter coupled to the emission control module, the adapter configured to receive an external ac power source and to convert ac power provided by the ac power source into dc power for use by the emission control module.

8. The wireless charging system of claim 1, wherein the battery housing is formed from a plastic material and the battery top cover and the battery bottom cover are bonded by ultrasonic processes.

9. Emergency rescue apparatus having a wireless charging system according to any one of claims 1 to 8.