CN221305765U - CT power supply and distribution device and CT power supply and distribution system - Google Patents

Abstract

The application relates to a CT power supply and distribution device and a CT power supply and distribution system, wherein the device comprises: the CT device comprises a power distribution module, an energy management module and a plurality of power supply adaptation terminals, wherein the plurality of power supply adaptation terminals are respectively connected with one end of the power distribution module, the other end of the power distribution module is connected with the CT device, and the energy management module is respectively connected with the plurality of power supply adaptation terminals and the power distribution module in a communication manner; the power supply voltage input circuit comprises a plurality of power supply adapter terminals, a plurality of power supply voltage input circuit and a power supply voltage input circuit, wherein the power supply adapter terminals are respectively adapted to power supply voltage inputs of a plurality of preset types; the power distribution module is used for converting the power supply voltage received by the plurality of power supply adaptive terminals into voltage required by the CT equipment, the single power distribution module is connected with the plurality of power supply adaptive terminals, and conversion of various power supply voltages can be realized based on the single energy change module, so that the internal volume of the CT power supply and distribution device is reduced, the cost of power supply and distribution materials of the CT equipment and the site matching construction cost are reduced, and the problems of high cost of the power supply and distribution materials and high operation cost of the CT are solved.

Description

CT power supply and distribution device and CT power supply and distribution system

Technical Field

The application relates to the field of CT power supply and distribution, in particular to a CT power supply and distribution device and a CT power supply and distribution system.

Background

The traditional CT power supply and distribution system supplies power and distributes power to the CT equipment based on electric energy provided by an external power supply, and specifically, the traditional CT power supply and distribution system is provided with a plurality of different independent power transformation device components, and the external power supplies with different voltage types and voltage values are respectively subjected to electric energy conversion so as to enable the CT equipment to operate. For this reason, in order to adapt to various field types, a scheme of distributing a plurality of power conversion components is generally adopted in the conventional CT power supply and distribution system. The characteristics of repetition, scattered layout and multiple types of power conversion components and parts make the total components and parts of the traditional CT power supply and distribution system numerous, and the occupied space is large, and the traditional CT power supply and distribution system has large requirements on the field power distribution capacity, so that the CT power supply and distribution equipment is expensive, the field matching construction cost is high, and the problems of generally high material cost and operation cost of the CT power supply and distribution system are caused.

At present, no effective solution is proposed for solving the problem of high cost of CT power supply and distribution in the related technology.

Disclosure of utility model

The embodiment of the application provides a CT power supply and distribution device and a CT power supply and distribution system, which are used for at least solving the problem of high cost of CT power supply and distribution in the related technology.

In a first aspect, an embodiment of the present application provides a CT power supply and distribution apparatus, including: the power distribution system comprises a power distribution module, a plurality of power supply adaptive terminals and an energy management module, wherein the power supply adaptive terminals are respectively connected with one end of the power distribution module, the other end of the power distribution module is connected with CT equipment, and the energy management module is respectively connected with the power supply adaptive terminals and the power distribution module in a communication way; wherein,

The power supply adaptation terminals are respectively adapted to power supply voltage inputs of various preset types;

The power distribution module is used for converting the power supply voltage received through the plurality of power supply adaptation terminals into the voltage required by the CT equipment.

In some embodiments, the power distribution module comprises an energy conversion module, the energy conversion module comprises a rectifying unit and an energy conversion unit, one end of the rectifying unit is connected with the plurality of power supply adaptive terminals, the other end of the rectifying unit is connected with one end of the energy conversion unit, and the other end of the energy conversion unit is connected with the CT equipment; wherein,

The rectification unit is used for converting alternating current into direct current;

The energy conversion unit is used for adjusting the voltage of the direct current.

In some of these embodiments, the energy conversion module comprises: the energy conversion unit is connected with the CT equipment, and is used for converting energy into power; wherein,

And the inversion unit is used for inverting and outputting the direct current into alternating current.

In some of these embodiments, the power distribution module further comprises: the energy storage module is connected with the energy conversion module; wherein,

The energy storage module is used for storing the electric energy output by the energy conversion module and/or outputting the stored electric energy to the energy conversion module.

In some of these embodiments, the energy storage module) includes: the electrochemical energy storage unit is connected with the electromagnetic energy storage unit; wherein,

The electrochemical energy storage unit is used for outputting electric energy to the energy conversion module and/or the electromagnetic energy storage unit at a first current multiplying power;

The electromagnetic energy storage unit is used for outputting electric energy to the energy conversion module at a second current multiplying power.

In some of these embodiments, the power distribution module further comprises: the sensor group is respectively in communication connection with the energy storage module and the energy management module;

the sensor group is used for detecting the working state of the energy storage module and generating an electric signal.

In some of these embodiments, the energy management module comprises: and the energy storage management unit is respectively in communication connection with the power supply adaptation terminal and the CT equipment.

In some of these embodiments, the energy management module comprises: and the controller unit is respectively in communication connection with the energy management module and the CT equipment.

In a second aspect, an embodiment of the present application provides a CT power supply and distribution system, including: the CT equipment is connected with the power distribution cabinet, and the power distribution cabinet comprises the CT power supply and distribution device according to any one of the embodiments of the first aspect.

In some of these embodiments, the CT apparatus comprises: a CT frame, a CT scanning support bed and a CT console.

Compared with the related art, the CT power supply and distribution device and the CT power supply and distribution system provided by the embodiment of the application have the advantages that a single power distribution module is connected with a plurality of power supply adaptation terminals, and the conversion of various power supply voltages can be realized only through one energy change module, so that the internal volume of the CT power supply and distribution device is reduced, the cost of power supply and distribution materials of CT equipment and the matched construction cost of a site are also reduced, and the problems of high cost of power supply and distribution materials and high operation cost of CT are solved.

The details of one or more embodiments of the application are set forth in the accompanying drawings and the description below to provide a more thorough understanding of the other features, objects, and advantages of the application.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute a limitation on the application. In the drawings:

FIG. 1 is a block diagram of a CT power supply and distribution apparatus according to an embodiment of the present application;

fig. 2 is a schematic diagram showing connection between the finishing unit and the power adapter terminal 2 according to an embodiment of the present application;

FIG. 3 is a block diagram of an energy storage module 13 according to an embodiment of the present application;

FIG. 4 is a block diagram of the energy management module 3 in one embodiment of the application;

FIG. 5 is a schematic diagram of a computed tomography imaging apparatus according to an embodiment of the present application;

FIG. 6 is a schematic diagram II of a computed tomography apparatus in accordance with an embodiment of the application;

FIG. 7 is a schematic diagram III of a computed tomography imaging apparatus in accordance with an embodiment of the application;

FIG. 8 is a block diagram of a CT power supply and distribution system in accordance with one embodiment of the present application;

FIG. 9 is a schematic diagram of an energy storage CT system according to an embodiment of the present application;

Fig. 10 is a schematic diagram of a second embodiment of an energy storage CT system.

Reference numerals: 1. a power distribution module; 10. an energy conversion module; 11. a rectifying unit; 12. an energy conversion unit; 121. a first transducer; 122. a second transducer; 123. a third transducer; 13. an energy storage module; 131. an electrochemical energy storage unit; 132. an electromagnetic energy storage unit; 14. a sensor group; 2. a power supply adapter terminal; 3. an energy management module; 31. a controller unit; 32. an energy storage management unit; 4. a CT apparatus; 5. a power distribution cabinet; u, a first three-phase alternating current terminal; v, a second three-phase alternating current terminal; a third three-phase ac terminal; l, single-phase alternating current terminal; DC. A DC input terminal; s1, a first switch; s2, a second switch; s3, a third switch.

Detailed Description

The present application will be described and illustrated with reference to the accompanying drawings and examples in order to make the objects, technical solutions and advantages of the present application more apparent. 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 application. All other embodiments, which can be made by a person of ordinary skill in the art based on the embodiments provided by the present application without making any inventive effort, are intended to fall within the scope of the present application. Moreover, it should be appreciated that while such a development effort might be complex and lengthy, it would nevertheless be a routine undertaking of design, fabrication, or manufacture for those of ordinary skill having the benefit of this disclosure, and thus should not be construed as having the benefit of this disclosure.

Reference in the specification to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment may be included in at least one embodiment of the application. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is to be expressly and implicitly understood by those of ordinary skill in the art that the described embodiments of the application can be combined with other embodiments without conflict.

Unless defined otherwise, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this application belongs. The terms "a," "an," "the," and similar referents in the context of the application are not to be construed as limiting the quantity, but rather as singular or plural. The terms "comprising," "including," "having," and any variations thereof, are intended to cover a non-exclusive inclusion; for example, a process, method, system, article, or apparatus that comprises a list of steps or modules (elements) is not limited to only those steps or elements but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus. The terms "connected," "coupled," and the like in connection with the present application are not limited to physical or mechanical connections, but may include electrical connections, whether direct or indirect. The term "plurality" as used herein means greater than or equal to two. "and/or" describes an association relationship of an association object, meaning that there may be three relationships, e.g., "a and/or B" may mean: a exists alone, A and B exist together, and B exists alone. The terms "first," "second," "third," and the like, as used herein, are merely distinguishing between similar objects and not representing a particular ordering of objects.

The present embodiment provides a CT power supply and distribution device, as shown in fig. 1, the device includes: the power distribution system comprises a power distribution module 1, a plurality of power supply adaptive terminals 2 and an energy management module 3, wherein the plurality of power supply adaptive terminals 2 are respectively connected with one end of the power distribution module 1, the other end of the power distribution module 1 is connected with a CT device 4, and the energy management module 3 is respectively connected with the plurality of power supply adaptive terminals 2 and the power distribution module 1 in a communication manner; wherein, the plurality of power supply adaptation terminals 2 are respectively adapted to the power supply voltage inputs of a plurality of preset types; a power distribution module 1 for converting a power supply voltage received through a plurality of power supply adaptation terminals 2 into a voltage required by the CT apparatus 4.

Wherein the preset type at least comprises one of the following: three-phase power, single-phase power and DC power. The CT power supply and distribution device is provided with a preset type of power supply by an external power supply. Alternatively, if the preset type of power source includes a three-phase power source, a single-phase power source, and a direct current power source, the power source adaptation terminal 2 includes a three-phase power source terminal, a single-phase power source terminal, and a direct current power source terminal corresponding to the preset type of power source voltage. The preset type of power source may also include a three-phase power source, a single-phase power source, and other types of power sources other than a direct current power source, which are not limited herein.

The power distribution module 1 can convert and output power supply voltage while keeping the type of external power supply unchanged, for example, the power distribution module 1 can convert alternating current of a first voltage into alternating current of a second voltage and output the alternating current to the CT device 4; the power distribution module 1 may also change the power supply type at the same time as converting the voltage, for example to achieve a conversion between an alternating voltage and a direct voltage.

The energy management module 3 is used for managing the power supply adaptive terminal 2 and the power distribution module 1, and the energy management module 3 can be implemented based on a microprocessor MCU, a programmable logic device FPGA, a single chip microcomputer or other existing chips, or a combination of the above chips. Illustratively, the energy management module 3 detects the type of power received by the power adapter terminal 2, the power voltage, and switches the operating state of the power distribution module 1 according to the type of power received by the power adapter terminal 2, the power voltage. Illustratively, when the preset type of power supply voltage meets the low power load power supply requirement in the CT apparatus 4, the energy management module 3 directly inputs the preset type of power supply voltage to the CT apparatus 4, and the power distribution module 1 does not convert the voltage.

In this embodiment, a single power distribution module 1 is connected to a plurality of power supply adapter terminals 2, so that multiple types of power supply voltages can be input to the same power distribution module 1 to realize the conversion of the power supply voltages. Compared with the prior art that different power supply voltages respectively correspond to the respective power supply adaptation terminals 2, the different power supply adaptation terminals 2 are connected with different electric energy conversion components, and in the embodiment, various power supply voltages can be converted through only one energy conversion module, so that the integrated design of the energy conversion module is realized, the internal volume of the CT power supply and distribution device is reduced, the requirements of CT power supply and distribution on the field power distribution capacity are reduced, and the total cost of a power supply and distribution system of the CT equipment 4 is also reduced.

Meanwhile, the power supply and distribution device of the CT equipment 4 comprising the energy conversion module is also characterized by high integration through the integrated design of the energy conversion module. Compared with the traditional CT power supply and distribution system, the CT power supply and distribution device in the embodiment can reduce the use amount of component-level cables and system-level cables, reduce the material cost, further improve the integrality of the power supply and distribution system and reduce the total space occupation of the power supply and distribution system on a hospital field by reducing the wire diameter of the system power supply cable. In addition, the CT power supply and distribution equipment in the conventional technology only supports three-phase alternating current input, and in this embodiment, the plurality of power supply adapter terminals 2 receive external power, so that the voltage input range supported by CT power supply and distribution and the supported electric energy types are enlarged.

On the basis of the connection structure of the power distribution module 1 and the power supply adapter terminal 2 in the present embodiment, the following embodiment describes units that may be included in the power distribution module 1.

In some of these embodiments, the power distribution module 1 includes an energy conversion module 10. The energy conversion module 10 comprises a rectifying unit 11 and an energy conversion unit 12, wherein one end of the rectifying unit 11 is connected with the plurality of power supply adaptive terminals 2, the other end of the rectifying unit 11 is connected with one end of the energy conversion unit 12, and the other end of the energy conversion unit 12 is connected with the CT equipment 4; wherein, the rectifying unit 11 is used for converting alternating current into direct current; and an energy conversion unit 12 for adjusting the voltage of the direct current. If the preset voltage includes single-phase alternating current, the rectifying unit 11 may implement single-phase alternating current rectification; if the preset voltage includes three-phase alternating current, the rectifying unit 11 may implement three-phase alternating current rectification. The energy transforming unit 12 may be used to transform the electric energy voltage output from the rectifying unit 11 into a voltage required for the operation of the CT apparatus 4. Taking the energy conversion unit 12 as an example of power supply of the main loop where the medium voltage generator and the bulb tube are positioned in the CT equipment 4, the energy conversion unit 12 can output kilovolt direct current, thereby reducing the energy conversion burden of the high voltage generator in the CT equipment 4 and achieving the effects of reducing the power transmission burden of the CT slip ring system and reducing the occupation of the rotor side space of the CT. If the CT power supply and distribution device further includes an energy storage module 13, the energy conversion unit 12 may be further configured to convert the electric energy voltage output by the rectifying unit 11 into a voltage required by the energy storage module 13 for energy storage.

Alternatively, the energy transforming unit 12 comprises a bi-directional DC/DC converter. When the alternating current is input to the CT power supply and distribution device, the rectifying unit 11 may include an ac-dc rectifier; when direct current is input to the CT power supply and distribution equipment, the rectifying unit 11 may include a direct current-direct current rectifier.

Fig. 2 is a schematic diagram of the power adapting terminal 2 and the rectifying unit 11 in the present embodiment, and as shown in fig. 2, the power adapting terminal 2 has three configurations in terms of external structure: a first three-phase ac terminal U, a second three-phase ac terminal V, and a third three-phase ac terminal W; a single-phase alternating-current terminal L; the direct current input terminal is the DC terminal in fig. 2. The single-phase ac input terminal L is connected to the rectifying unit 11 through the first switch S1, and the DC terminal is connected to the energy conversion unit 12 through the second switch S2. Wherein the power supply adapter terminals 2 each support a wide voltage range input, and the specific wide voltage range can be set according to application requirements. Alternatively, the power supply-adaptive terminals 2 configured as the above three appearance structures are provided as terminals supporting three-phase power supply inputs of 300Vac to 500Vac, single-phase power supply inputs of 80Vac to 270Vac, and direct-current inputs of 40Vac to 300Vac, respectively. Based on the power supply adaptation terminal 2, various power supply type inputs can be compatible to use sites with different power supply quality.

The rectifying unit 11 includes 4 sets of bridge arms, an inductor, and a dc bus capacitor. The bridge arm group 1 comprises a diode D1 and a diode D2 which are connected in series, the bridge arm group 2 comprises a diode D3 and a diode D4 which are connected in series, the bridge arm group 3 comprises a diode D5 and a diode D6 which are connected in series, and the bridge arm group 4 comprises a diode D7 and a diode D8 which are connected in series.

When the external power supply outputs three-phase alternating current, the bridge arm group 1, the bridge arm group 2 and the bridge arm group 3 form a three-phase alternating current rectifying circuit so as to carry out three-phase bridge rectification. When the external power supply outputs single-phase alternating current, any one of the bridge arm groups 1, 2 and 3 and the bridge arm group 4 form a single-phase alternating current rectifying circuit to carry out single-phase bridge rectification. The inductor and the DC bus capacitor form a DC bus filter, and the rectified DC voltage waveform is subjected to smooth conditioning and EMI (Electromagnetic INTERFERENCE EMI FILTERING) filtering. When the external power supply outputs direct current, the direct current is directly input to the energy conversion unit to regulate the voltage level so as to output power to the CT equipment and/or store energy to charge the energy storage module.

Fig. 2 further comprises an energy management module 3, the energy management module 3 being in communicative connection with the power adapter terminals 2, S1, S2. The energy management module 3 further includes a voltage and current sensing probe, and the energy management module 3 controls the rectifying unit 11 to perform ac-dc rectification, dc-dc rectification or not to perform rectification by controlling on-off of the S1 and S2.

When the controller unit 31 in the energy management module 3 judges that the external power supply inputs three-phase alternating current (such as 380Vac, 400Vac three-phase alternating current and the like) according to the voltage and current sensing probe signals, the controller unit 31 issues a command to an alternating current-direct current rectifier in the rectifying unit 11 to execute three-phase rectifying and filtering operation, and at the moment, a three-phase alternating current rectifying circuit formed by the bridge arm group 1, the bridge arm group 2 and the bridge arm group 3 carries out bridge rectification to provide electric energy input for the CT equipment 4 system;

When the controller unit 31 determines that the external power source inputs single-phase ac power (such as single-phase ac power of 220Vac, 230Vac or 110 Vac) according to the voltage and current sensing probe signal, the single-phase ac terminal L is connected to the live wire port of the mains socket, and any one of the terminals U, V, W is connected to the neutral wire port of the mains socket, so as to form a loop for receiving the single-phase ac power of the mains. The controller unit 31 issues a command to close the command control switch S1 and issues a command to the ac/dc rectifier in the rectifying unit 11 to perform single-phase rectification, and at this time, any one of the bridge arm groups 1, 2, 3 and 4 forms a single-phase ac rectifying circuit to provide electric energy input for the CT device 4 system

When the controller unit 31 determines that the external power input is direct current according to the voltage and current sensing probe signal, the controller unit 31 issues a command to control the ac/dc rectifier in the rectifying unit 11 not to start running and control the switch S2 to be closed, the direct current is input to the dc-dc converter in the power distribution module 1, and the direct current is output to provide electric energy input for the CT equipment 4 system through electric energy voltage regulation and conversion.

The user may use one of the three power adapter terminals 2 depending on the actual field power socket type. The CT system device may then detect the type of voltage input via sensor set 14 to automatically select the adapter circuit to provide power input to CT device 4.

In some of these embodiments, the energy conversion module 10 includes: an inversion unit, one end of which is connected with the energy conversion unit 12, and the other end of which is connected with the CT equipment 4; the inversion unit is used for inverting and outputting the direct current into alternating current.

The inverter unit is used for converting the direct current voltage output by the energy conversion unit 12 into an alternating current voltage required by an alternating current load in the CT device 4. The inverter unit includes a single-phase inverter, a three-phase inverter, or a combination of both inverters. The inversion unit can output three-phase alternating current to supply power for a main driver of a accelerating motor or other three-phase alternating current input auxiliary loads in the CT equipment 4; the single-phase alternating current can be output to supply power for the single-phase alternating current input auxiliary load of the CT equipment 4 with the single-phase alternating current power supply requirement. Alternatively, the single-phase inverter is a high-frequency high-voltage high-power inverter (e.g., output 20kHz to 200kHz, 500Vac to 2000 Vac), and is used by a contactless power transfer slip ring in the CT apparatus 4 to supply electric power to a main circuit in the CT apparatus 4, such as a high-voltage generator bulb.

The inverter may include a main inverter for providing a high power supply for the CT main loop (high voltage generator and bulb); the auxiliary inverter is used for supplying power to a series of loads (such as a main motor and the like) with alternating current input requirements on the CT auxiliary loop.

Optionally, the power distribution module 1 further includes: the filtering unit, one end of the filtering unit is connected with a plurality of power supply adaptive terminals 2, and the other end of the filtering unit is connected with the energy management module 3; the filtering unit is used for smoothing and filtering the power supply voltage input to the power distribution module 1, reducing EMI and improving the quality of the input electric energy of the front stage.

In the conventional technology, the CT power supply and distribution equipment only supports three-phase ac power input, and if the quality of the external power supply is problematic, the operation safety of the CT equipment 4 cannot be guaranteed. To solve this problem, in the next embodiment, an energy storage module 13 is provided, and seamless and uninterrupted power supply is provided for the operation of the CT apparatus 4 through the energy storage module 13.

In some of these embodiments, the apparatus further comprises: the energy storage module 13, the energy storage module 13 is connected with the energy conversion module 10; the energy storage module 13 is configured to store the electric energy output by the energy conversion module 10 and/or output the stored electric energy to the energy conversion module 10.

When the external power input exists, the external power can be directly output to the CT equipment 4 after the voltage is converted by the energy conversion module 10, and can also be output to the energy storage module 13 after the voltage is converted by the energy conversion module 10. When the CT apparatus 4 is operated, the energy storage module 13 may output electric energy to the energy conversion module 10, and the voltage is converted by the energy conversion module 10 and input to the CT apparatus 4. The energy storage module 13 in this embodiment can support the long-time execution of the medical scanning task by the CT under the working condition without the external power source, so as to solve the problem that the CT device 4 cannot operate normally when the power quality of the external power source is problematic.

Alternatively, fig. 3 provides a schematic diagram of an energy storage module 13, and as shown in fig. 3, the energy storage module 13 includes: the electrochemical energy storage unit 131 and the electromagnetic energy storage unit 132, wherein the electrochemical energy storage unit 131 is connected with the electromagnetic energy storage unit 132; wherein, the electrochemical energy storage unit 131 is configured to output electric energy to the energy conversion module 10 and/or the electromagnetic energy storage unit 132 at a first current multiplying power; the electromagnetic energy storage unit 132 is configured to output electric energy to the energy conversion module 10 at the second current multiplying power.

The electrochemical energy storage unit 131 is a unit for realizing electric energy storage based on interaction of electric and chemical reactions, and can be a lithium ion battery, a lead-acid battery, a nickel ion battery, a sodium ion battery and a combination type of the above batteries. The electromagnetic energy storage unit 132 includes a unit for realizing electric energy storage based on electromagnetic interaction, and may be a super capacitor, a superconducting magnetic energy storage, a capacitor module, and the like. Optionally, the electromagnetic energy storage unit 132 comprises super capacitors connected in parallel with each other, and the electrochemical energy storage unit 131 comprises a lithium ion battery.

Based on the high energy density advantage of the electrochemical energy storage unit 131, the high power density advantage of the electromagnetic energy storage unit 132, the first current multiplying power is smaller than the second current multiplying power. The electrochemical energy storage unit 131 can realize high-capacity electric energy storage; the electromagnetic energy storage unit 132 may provide a transient very high power discharge. Optionally, the electrochemical energy storage unit 131 is used for charging the electromagnetic energy storage unit 132, and the electromagnetic energy storage unit 132 is used for meeting the high-power supply requirement of the CT apparatus 4, so that the CT apparatus 4 is supported to execute the medical scanning task for a long time under the working condition without an external power supply according to the reasonable configuration of the energy storage capacity of the electrochemical energy storage unit 131 in the energy storage module 13.

In this embodiment, based on the electrochemical energy storage unit 131 and the electromagnetic energy storage unit 132 in the energy storage module 13, the composite energy storage of the mixed electric energy of the energy storage module 13 is realized, so that the energy storage module 13 provides electric energy sources with different energy densities and power densities for the system of the CT apparatus 4, so as to adapt to the power requirements of various apparatuses in the CT apparatus 4 under various conditions, for example, the instantaneous high-power supply requirements of the bulb pay-off in the CT apparatus 4.

In one embodiment, the power distribution module 1 further comprises: the sensor group 14, the sensor group 14 is connected with the energy storage module 13; the sensor group 14 is used for detecting the working state of the energy storage module 13 and generating an electric signal. Wherein, the sensor group 14 at least comprises one of the following: voltage sensor group, current sensor group, temperature sensor group and humidity sensor group. The working state of the energy storage module 13 can be obtained at any time through the sensor group 14, and whether the energy storage module 13 is in a normal running state or not is judged.

In one embodiment, the energy management module 3 comprises: the energy storage management unit 32, the energy storage management unit 32 is connected with the power adaptation terminal 2 and the CT equipment 4 in a communication way respectively. The energy storage management unit 32 is used for performing real-time state monitoring and charge-discharge strategy analysis on the electromagnetic energy storage unit 132 and the electrochemical energy storage unit 131.

In one embodiment, the energy management module 3 comprises: the controller unit 31, the controller unit 31 is communicatively connected to the energy management module 3 and the CT apparatus 4, respectively. The controller unit 31 is configured to control an operation state of the power distribution module 1 according to the monitoring result and the policy analysis of the energy storage management unit 32.

In one embodiment, the energy management module 3 comprises: an energy storage management unit 32 and a controller unit 31. Illustratively, the energy storage management unit 32 includes an energy storage sensing monitor and an energy storage management MCU (Microcontroller Unit, microcontroller). The controller unit 31 includes a communication circuit, a DSP chip (DIGITAL SIGNAL processes, digital signal processing), a driver, and a switching device.

The energy storage sensing monitor is used for acquiring the electric signals generated by the sensor group 14 in real time, the energy storage management MCU is used for processing the electric signals acquired based on the energy storage sensing monitor to obtain real-time and detailed state evaluation parameters of the energy storage module 13, and the current state evaluation parameters are used for providing references and criteria for the electric power demand and the electric power consumption demand required by the CT equipment 4 when the CT equipment 4 executes one or more subsequent CT scanning tasks.

Taking the example that the energy storage management unit 32 monitors the health status of each supercapacitor cell in the electromagnetic energy storage unit 132 and each lithium ion battery cell in the electrochemical energy storage unit 131, the status evaluation parameters acquired by the energy storage management MCU at least include one of the following: each cell voltage, total voltage; each single current, total current; SOC (State of Charge) estimation, SOH (State of Health) estimation, SOP (State of Power) estimation; collecting the temperature of a battery monomer; and (5) carrying out balanced management on the battery cells.

When the charge and discharge tasks of the energy storage module 13 are involved, the energy storage management MCU cooperates with the communication circuit, the DSP and the driver in the controller unit 31. The communication circuit is used for realizing signal intercommunication among all modules and units, and the DSP and the driver control the grid-driven switch of the power semiconductor switching device in the power distribution module 1 according to the instruction output by the energy storage management MCU so as to realize the accurate control of the power level voltage and current output in the power distribution module 1. Wherein the switching devices in the controller unit 31 comprise at least one of the following: hard switch, relay and contactor in power supply and distribution equipment. The isolated drive circuit is one possible form of gate drive that is used to improve the electromagnetic compatibility EMC (Electromagnetic Compatibility ) performance of the system.

To ensure the quality of the supplied electrical energy, the controller unit 31 is optionally also used to control the energy supply mode of the energy storage module 13. Wherein the controller unit 31 comprises a voltage current sensing probe signal. The controller unit 31 monitors the electric energy of the power input terminal through the voltage and current sensing probe signal, and analyzes and judges the electric energy input quality in cooperation with the energy storage management unit 32. Wherein the parameters for analyzing the power quality include at least one of: transient overvoltage, frequency fluctuation, voltage surge or dip, flicker, transient power failure, harmonics, inter-harmonics, unbalance, and the power quality can be analyzed by other power parameters, which are not limited herein. If it is determined that there is a possibility of abnormality in the power quality based on at least one of the above parameters, a command is issued to the controller unit 31 through the energy storage management unit 32 to control the energy storage module 13 to switch into the full energy storage power supply mode. In the full energy storage power supply mode, the power supply of the CT equipment 4 is changed from the external power supply to the power supply of the energy storage module 13, so that the input voltage of the high-voltage generator of the CT equipment 4 is ensured to be in a stable state at all times, and the X-ray tube of the CT equipment 4 can normally complete the paying-off task. The power-off self-protection work is not needed to be executed by the X-ray tube as in the traditional technology, so that unnecessary losses of hospitals and patients to be scanned caused by power supply faults, downtime, power failure and other emergency conditions of the CT equipment 4 are avoided.

In some of these embodiments, fig. 5 provides a schematic diagram of a hybrid power device. As shown in fig. 5, the hybrid power supply device is connected to the CT apparatus 4, and a network power supply supplies a plurality of preset types of power supply voltages to the hybrid power supply device. The CT device 4 comprises a low-power load, a high-voltage generator, an X-ray tube and a hybrid power supply device, wherein the high-voltage generator is connected with the X-ray tube. The hybrid power supply device comprises a power supply adapter terminal 2, a first energy changer 121, a second energy changer 122, a third energy changer 123 in the energy changer unit 12, an electrochemical energy storage unit 131, an electromagnetic energy storage unit 132 in the energy storage module 13, and an energy management module 3. Wherein the first transformer 121, the second transformer 122 and the third transformer 123 are used for transforming the supply voltage.

The power supply adaptation terminal 2 is connected to the first transformer 121, the second transformer 122, and the low power load in the CT apparatus 40, respectively. The first transformer 121 is connected to the second transformer 122 and the low power load in the CT apparatus 4, respectively, and the first transformer 121 is connected to the high voltage generator. The second energy converter 122 is respectively connected with the electrochemical energy storage unit 131 and the electromagnetic energy storage unit 132, and the third energy converter 123 is respectively connected with the electrochemical energy storage unit 131 and the electromagnetic energy storage unit 132. The high-voltage generator is movably connected with the electromagnetic energy storage unit 132 and the first energy changer 121 through a third switch S3.

In the energy storage module 13, the electromagnetic energy storage unit 132 is of a power type and mainly supplies power to the high-voltage generator in the CT equipment 4 so as to meet the high power density requirement of the high-voltage generator of the CT equipment 4. The electrochemical energy storage unit 131 at least comprises one of the following lithium ion battery, lead-acid battery, nickel ion battery and sodium ion battery. The electrochemical energy storage unit 131 is an energy type energy storage unit, and is mainly used for providing electric energy for the electromagnetic energy storage unit 132, wherein the electrochemical energy storage unit 131 at least comprises one of the following lithium ion battery, sodium ion battery and nickel ion battery.

In the energy transforming unit 12, the first energy transformer 121 may include a passive rectifying circuit and/or an active rectifying circuit, a DC/DC converter; the second energy converter 122 is mainly used for converting network voltage to charge the electromagnetic energy storage unit 132 and the electrochemical energy storage unit 131; the third transformer 123 is mainly used for converting the electric energy voltage output from the electrochemical energy storage unit 131 to charge the electromagnetic energy storage unit 132. Optionally, the second energy converter 122 includes a bidirectional DC/DC converter, and the voltage of the electric energy output to the second energy converter 122 by the network power source or the electric energy conversion module is boosted (e.g. 550Vdc to 1000 Vdc) or reduced (e.g. 500Vdc to 50 Vdc) by the bidirectional DC/DC converter, so that the voltage meets the charging requirement of the electromagnetic energy storage unit 132 and/or the charging requirement of the electrochemical energy storage unit 131. The third energy converter 123 includes a bidirectional DC/DC converter, and is disposed between the electrochemical energy storage unit 131 and the electromagnetic energy storage unit 132, and can boost the electric energy voltage input from the electrochemical energy storage unit 131 to the third energy converter 123, so that the electric energy voltage input from the electrochemical energy storage unit 131 to the electromagnetic energy storage unit 132 meets the charging requirement of the electromagnetic energy storage unit 132.

Optionally, an energy storage management unit 32 and a controller unit 31 are included in the energy management module 3. The controller unit 31 is connected to the electrochemical energy storage unit 131, the electromagnetic energy storage unit 132, the second energy converter 122 and the third energy converter 123, respectively. The energy storage management unit 32 is used for monitoring states of the electrochemical energy storage unit 131 and the electromagnetic energy storage unit 132, and controls working states of the second energy converter 122 and the third energy converter 123 through the controller unit 31; the third switch S3 is controlled to switch according to the scanning protocol to selectively supply power to the high voltage generator by the first transducer 121 or the energy storage module 13. Optionally, the energy management module 3 may include a central MCU chip of the composite energy storage system, an energy management policy controller EMS (Energy Management Strategy) chip, or a 'SoC system on a chip' formed by integrating the MCU chip and the EMS chip, a plurality of digital signal processing and interface circuits, a digital signal processing chip, and a semiconductor power switching transistor gate driving controller. The energy management module 3 changes the state of the third switch S3 according to the power level of the scanning protocol of the CT apparatus 4, and the first transducer 121 or the electromagnetic energy storage unit 132 supplies power to the high voltage generator.

The hybrid power supply and distribution device in the present embodiment can supply and distribute power to the CT apparatus 4. As shown in fig. 5, the hybrid power supply device may enable the low power load in the CT apparatus 40 to directly draw power from the mains electricity, and the high power voltage generator to draw power from the mains electricity or the electromagnetic energy storage unit.

Illustratively, the mains power supply inputs electrical energy to the first transformer 121 via the power adapter terminal 2. Wherein the network electrical input may be a multi-phase or single-phase ac voltage. The first inverter 121 rectifies the ac power to obtain dc power, then boosts or steps down the dc power, and outputs the boosted or stepped down dc power to the high voltage generator. The dc voltage after the step-up or step-down process may be consistent with the dc voltage output by the electromagnetic energy storage unit 132, so as to meet the operation requirement of high-power paying-off of the high-voltage generator. The dc voltage may also be in accordance with the supply voltage of each low-power load in the CT apparatus 4 or in accordance with the voltage at the time of low-power line-out of the high-voltage generator. The network power supply may also directly power the low power load.

The network power supply may input electric energy to the second energy converter 122, rectify the ac electric energy by the second energy converter 122 to obtain dc electric energy, boost or buck the dc electric energy, and output the boosted or decompressed dc electric energy to the electrochemical energy storage unit 131 and/or the electromagnetic energy storage unit 132. The electromagnetic energy storage unit 132 is configured to output a dc voltage to the high voltage generator, where the dc voltage is consistent with a power supply voltage of the high voltage generator during high-power paying-off. The electrochemical energy storage unit 131 is used to charge the electromagnetic energy storage unit 132. For example, when the energy storage management unit 32 monitors that the SOC of the lithium-ion battery in the electrochemical energy storage unit 131 reaches the lower limit value, the second transducer 122 outputs direct current to charge the lithium-ion battery in the electrochemical energy storage unit 131. When the energy storage management unit 32 monitors that the super capacitor in the electromagnetic energy storage unit 132 needs to be charged (the SOC is rapidly reduced or reaches the lower limit value), the electrochemical energy storage unit 131 outputs the direct current to the third energy converter 123, the third energy converter 123 boosts the direct current, and the boosted direct current is output to the electromagnetic energy storage unit 132. Thus, the charging energy of the super capacitor in the electromagnetic energy storage unit 132 may be from the lithium ion battery in the electrochemical energy storage unit 131, or from the mains power supply.

In this embodiment, according to the characteristics that the high voltage generator of the CT apparatus 4 has a large paying-off power range and the CT apparatus 4 has a low power load, the high voltage generator and other low power loads are separately powered: the electromagnetic energy storage unit 132 (such as a super capacitor bank) or the network power supply converted by the electric energy conversion unit meets the high-power paying-off requirement of the high-voltage generator; the low power load and/or high voltage generator low power pay-off requirements are met by the network power supply. The electrochemical energy storage unit 131 can charge in a peak-shifting manner while reducing the field distribution capacity and line requirements of the CT equipment 4, so that the energy conservation and the reduction of the operation cost of the CT equipment 4 are realized.

In one embodiment, the first transducer 121 may not be included in the hybrid power device. Fig. 6 provides a schematic diagram of a hybrid power supply device. As shown in fig. 6, the hybrid power supply device is connected to the CT apparatus 4. The CT apparatus 4 includes a low power load, a high voltage generator, an X-ray tube, and a hybrid power supply device, wherein the high voltage generator is connected to the X-ray tube. The network power supply supplies electric energy to the hybrid power supply device through the power supply adapter terminal 2. The power supply adapter terminal 2 is connected to the second transformer 122 and a low power load. The second energy converter 122 is connected to the electrochemical energy storage unit 131 and the electromagnetic energy storage unit 132, respectively. The third energy converter 123 is connected to the electrochemical energy storage unit 131 and the electromagnetic energy storage unit 132, respectively. The electromagnetic energy storage unit 132 is connected with a high voltage generator. The energy management module 3 is in communication with the second energy converter 122, the third energy converter 123, the electrochemical energy storage unit 131, and the electromagnetic energy storage unit 132, respectively. At this time, the power supply requirement of the low power load is satisfied by the network power supply based on the electromagnetic energy storage unit 132 satisfying the high power supply requirement of the high voltage generator.

In one embodiment, the electrochemical energy storage unit 131 and the third energy converter 123 may not be included in the hybrid power device. Fig. 7 provides a schematic diagram III of a hybrid power supply device. As shown in fig. 7, the hybrid power supply device is connected to the CT apparatus 4. The CT apparatus 4 includes a low power load, a high voltage generator, an X-ray tube, and a hybrid power supply device, wherein the high voltage generator is connected to the X-ray tube. The network power supply supplies electric energy to the hybrid power supply device through the power supply adapter terminal 2. The power supply adapter terminal 2 is connected to the first transformer 121, the second transformer 122, and the low power load in the CT apparatus 4, respectively. The first transformer 121 is connected to a low power load, and the second transformer 122. The second transducer 122 is connected to an electromagnetic energy storage unit 132. The high-voltage generator is movably connected with the electromagnetic energy storage unit 132 and the first energy changer 121 through a third switch S3. The energy management module 3 is communicatively connected to the second transducers 122, S3, respectively. In this embodiment, the electromagnetic energy storage unit 132 may be used to meet the requirement of high-power paying-off scanning of the main circuit where the high-voltage generator and the bulb are located, and the network power supply meets the power supply requirement of the auxiliary load in the CT apparatus 4. The energy management module 3 controls the third switch S3, and the network power supply or the electromagnetic energy storage unit 132 meets the requirement of the main loop high-voltage generator and the main loop where the bulb tube is located for low-power paying-off scanning.

In some embodiments, a CT power supply and distribution system is further provided, where the CT power supply and distribution system may implement the foregoing embodiments and preferred implementations, and the description is omitted herein. As used below, the terms "module," "unit," "sub-unit," and the like may be a combination of software and/or hardware that implements a predetermined function. While the means described in the following embodiments are preferably implemented in software, implementation in hardware, or a combination of software and hardware, is also possible and contemplated.

In one embodiment, fig. 8 is a block diagram of a CT power supply and distribution system according to this embodiment, and as shown in fig. 8, the apparatus includes: the CT equipment 4 and the power distribution cabinet 5, the CT equipment 4 is connected with the power distribution cabinet 5, and the power distribution cabinet 5 comprises a CT power supply and distribution device in any device embodiment. Optionally, the CT apparatus 4 includes: a CT frame, a CT scanning support bed and a CT console.

In one embodiment, fig. 9 is a schematic diagram of a structure of an energy storage type CT system in the present embodiment. As shown in fig. 9, the energy storage type CT system includes a power adapter terminal 2, a power distribution module 1, an energy management module 3, and a CT apparatus 4, and the CT apparatus 4 includes a CT gantry, a scanning support bed, and a console part. The CT frame comprises a detector module, a high-voltage generator, an X-ray tube, a rotor part auxiliary load, a stator part auxiliary load and a main motor. The field power supply provides various preset types of power supply voltages for the energy storage type CT system.

The power adapter terminal 2 includes a multiphase input terminal, a single-phase input terminal, and a direct current input terminal. Wherein the multiphase inputs include, but are not limited to: the three-phase network power supply terminal, the bridge rectifier circuit and the power factor correction circuit. Single phase inputs include, but are not limited to: a single-phase mains supply terminal, a bridge rectifier circuit. The dc input includes, but is not limited to, a dc power terminal.

The power distribution module 1 comprises a power distribution module 1, an energy storage module 13 and a sensor group 14, and specifically, the power distribution module 1 comprises the following units but is not limited to: the energy conversion unit 12, the filtering unit, the inversion unit and the transformer. The energy storage module 13 may include at least one electromagnetic energy storage unit 132 and at least one electrochemical energy storage unit 131, and may also include a combination of the electromagnetic energy storage unit 132 and the electrochemical energy storage unit 131. A power distribution system sensor set 14 comprising at least one of the following: voltage sensors, current sensors, temperature sensors, humidity sensors, etc.

The energy management module 3 includes the energy management module 3 therein. The energy management module 3 comprises an energy storage management unit 32 and a controller unit 31. Wherein the energy storage management unit 32 includes, but is not limited to, at least one energy storage management MCU chip, at least one energy storage sensing monitor; the controller unit 31 includes, but is not limited to, communication circuitry, at least one DSP and drivers, and various switching devices.

Wherein, the straight line arrow in fig. 9 is used to indicate the flowing direction of the power flow in the energy storage type CT system, and the broken line arrow is used to indicate the signal communication direction in the energy storage type CT system.

In one embodiment, fig. 10 provides a schematic diagram of a second energy storage type CT system, where the power distribution module 1 includes an ac-dc rectifier, a plurality of dc-dc converters, and an ac-dc inverter. The energy storage module 13 includes an electromagnetic energy storage unit 132 and an electrochemical energy storage unit 131. The sensor group 14 includes: an energy storage end voltage sensor group 14, an energy storage current sensor group 14, a temperature sensor group 14 and a humidity sensor group 14.

The dc-ac inverter in the power distribution module 1 may be disposed and installed on the stationary side of the CT apparatus 4 system, or may be disposed and installed on the stationary side or the rotor side of the CT gantry. The type of voltage output by the power distribution module 1 to the high-voltage generator can be voltage in the form of alternating current (such as kHz frequency), pulse voltage (such as kHz square wave and triangular wave) or pure direct current; when the output of the power distribution module 1 is in a pure direct-current voltage form, a high-voltage inversion unit can be additionally arranged on the front side of the high-voltage generator.

In this embodiment, the electromagnetic energy storage unit 132 is mainly responsible for providing high-power density electric energy for the high-voltage generator and the bulb tube of the CT, and the power flow corresponding to the high-power density electric energy is indicated by the thickest arrow line segment in the figure. The electrochemical energy storage unit 131 is mainly responsible for powering the detector modules of the CT, the scanning support bed, the console components, the CT gantry main motor and all auxiliary loads. The electrochemical module can comprise a hydrogen fuel cell stack and a lithium battery pack, and the replacement of the hydrogen fuel cell stack and the lithium battery pack can be realized through a pluggable scheme. The electromagnetic energy storage unit 132 may be composed of super capacitors connected in series and parallel, the charging voltage is dc, and when the electromagnetic energy storage unit 132 is charged, the source of electric energy may be from the output of the dc-dc converter in the power distribution module 1, and the electric energy output from the dc-dc converter to the electromagnetic energy storage unit 132 may be from the electric energy output from the power supply adapter terminal 2 through the ac-dc converter and the dc-dc converter in sequence, or from the electric energy output from the electrochemical energy storage unit 131 through the dc-dc converter.

The energy storage type CT system in this embodiment can supply and distribute power to the CT apparatus 4, specifically as follows: when the CT is powered by an external power source (e.g., three-phase mains, single-phase mains, dc power), the detector modules of the CT, the scanning support bed, the console components, the CT gantry main motor, and all auxiliary loads are powered primarily from the external power source. Under the working condition, the electrochemical energy storage unit 131 formed by the lithium ion battery pack is mainly used for carrying out adjustable and controllable quick charge on the electromagnetic energy storage unit 132 formed by the super capacitor pack. Specifically, after the supercapacitor bank executes the scanning protocol task with high power and high energy, if another scanning task with high power and high energy is about to follow, the state of the electromagnetic energy storage unit 132 is monitored in real time by the energy storage sensing monitor in the energy storage management unit 32, and the energy storage management MCU determines the expected state of the electromagnetic energy storage unit 132 based on the detection result. If the state end voltage and the remaining amount of electricity of the electromagnetic energy storage unit 132 do not meet the next paying-off power and electricity demand requirements, the energy storage management unit 32 and the controller unit 31 perform high-rate discharge control for the electrochemical energy storage unit 131, for example, discharge at a rate of 500V/80A at 8C rate. The electrochemical energy storage unit 131 is rapidly charged to the electromagnetic energy storage unit 132 through high-rate discharge, for example, the electromagnetic energy storage unit 132 is charged in seconds, so as to be ready for the next scanning task.

Alternatively, modular expansion may be performed on the basis of the power distribution module 1, such as adding a water cooled heat dissipation thermal management subsystem. The heat management subsystem based on water cooling heat dissipation controls the temperature of each unit in the energy storage module 13 in an ideal state range, and the sensor group 14 and the energy management module 3 coordinate to execute monitoring and water cooling control strategies so as to prevent the power distribution module 1, particularly the energy storage module 13 from being out of control, and avoid safety accidents. An active ventilation subsystem may also be added to the power distribution module 1. The active ventilation subsystem is used for carrying out real-time type and quantitative monitoring on the gas in the device provided with the energy storage type CT system, and the ventilation work in the system is actively carried out according to the detection result, so that the air environment in the system is kept good. The energy storage module 13 is prevented from generating gases such as hydrogen, carbon dioxide, carbon monoxide, hydrocarbons and the like due to overlarge instantaneous thermal pressure under the high-power high-load high-current charge and discharge working state, so that the potential combustible hidden trouble is brought to the system environment, the low toxicity is brought to the human body, the occurrence of safety accidents is avoided, and uncomfortable influence on the human body in the field environment is avoided. Specifically, the energy storage sensing monitor and the energy storage management MCU analyze the electrical signals output by the voltage, current, temperature and humidity sensors in the sensor group 14 to obtain the trend of environmental condition change and state analysis, so as to determine whether to execute active ventilation. When it is determined that the active ventilation operation is required, the controller unit 31 controls the active ventilation subsystem to exhaust the exhaust gas of the internal ambient gas around the energy storage module 13 and replace new air.

Alternatively, a high voltage platform may be introduced on the basis of the power distribution module 1 to achieve higher overall system transduction efficiency. Wherein the introduced platform is a 1200V high voltage platform, on the basis of which a power conversion component of a 1200V SiC MOSFET (silicon carbide power semiconductor) is introduced into the power distribution module 1. Based on the advantages of the silicon carbide power semiconductor device in the aspects of on-resistance, blocking voltage and heat dissipation, the energy conversion efficiency of the CT whole system is greatly improved, meanwhile, the heat management system/heat dissipation design difficulty of the CT equipment 4 system is greatly reduced, and the stability of the CT equipment 4 system is improved. And the volume of the energy storage type CT system constructed based on the silicon carbide power semiconductor is reduced by one third compared with that of the energy storage type CT system constructed based on the traditional Si silicon-based semiconductor, thereby creating conditions for high integration and miniaturization of the CT system and reducing the realization cost.

In this embodiment, based on the power distribution module 1 and the energy management module 3, the functions of energy storage, electric energy conversion and power distribution are integrated in the energy storage type CT system, so as to greatly reduce the site power distribution capacity of the CT apparatus 4 (for example, from hundreds of kVA to less than kVA), and reduce the comprehensive power supply and distribution cost of the CT apparatus 4 system, wherein the power supply and distribution cost includes the capacity configuration cost of the industrial and commercial network power input transformer, the site transformation cost, and the like. The energy storage type CT system is applied to the CT distribution box, so that the energy storage type CT distribution box has the characteristics of miniaturization and high integration of the CT distribution box, and the defects of high requirements on field distribution capacity, huge and compact size and the like of the distribution box 5 of the traditional CT equipment 4 are overcome.

Alternatively, the semiconductor power switching transistors used in all the devices related to power conversion in the above embodiments are not limited to silicon-based IGBTs (Insulate-Gate Bipolar Transistor, insulated gate bipolar transistors), gallium nitride and/or silicon carbide-based MOSFETs (metal-oxide semiconductor FET, metal-oxide semiconductor field effect transistors), and the withstand voltage level of the semiconductor power switching transistors is not limited to 400V to 1200V. The digital signal processing chip in the energy management module 3 is not limited to a conventional DSP processor, an FPGA singlechip, an ARM singlechip and a special MCU, and the specific chip can be replaced by a scheme according to performance requirements.

It should be understood by those skilled in the art that the technical features of the above-described embodiments may be combined in any manner, and for brevity, all of the possible combinations of the technical features of the above-described embodiments are not described, however, they should be considered as being within the scope of the description provided herein, as long as there is no contradiction between the combinations of the technical features.

The foregoing examples illustrate only a few embodiments of the application and are described in detail herein without thereby limiting the scope of the application. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims.

Claims (10)

1. A CT power supply and distribution device, said device comprising: the power distribution system comprises a power distribution module (1), a plurality of power supply adaptive terminals (2) and an energy management module (3), wherein the plurality of power supply adaptive terminals (2) are respectively connected with one end of the power distribution module (1), the other end of the power distribution module (1) is connected with a CT device (4), and the energy management module (3) is respectively connected with the plurality of power supply adaptive terminals (2) and the power distribution module (1) in a communication manner; wherein,

The power supply adaptation terminals (2) are respectively adapted to power supply voltage inputs of a plurality of preset types;

The power distribution module (1) is used for converting the power supply voltage received through the plurality of power supply adaptation terminals (2) into the voltage required by the CT equipment (4).

2. The CT power supply and distribution apparatus as recited in claim 1, wherein the power distribution module (1) includes an energy conversion module (10), the energy conversion module (10) includes a rectifying unit (11) and an energy conversion unit (12), one end of the rectifying unit (11) is connected to the plurality of power supply adaptation terminals (2), the other end of the rectifying unit (11) is connected to one end of the energy conversion unit (12), and the other end of the energy conversion unit (12) is connected to the CT device (4); wherein,

The rectification unit (11) is used for converting alternating current into direct current;

the energy conversion unit (12) is used for adjusting the voltage of the direct current.

3. The CT power supply and distribution device as recited in claim 2, wherein the energy conversion module (10) comprises: an inversion unit, one end of which is connected with the energy conversion unit (12), and the other end of which is connected with the CT equipment (4); wherein,

And the inversion unit is used for inverting and outputting the direct current into alternating current.

4. The CT power supply and distribution device as recited in claim 2, wherein the power distribution module (1) further comprises: the energy storage module (13) is connected with the energy conversion module (10); wherein,

The energy storage module (13) is used for storing the electric energy output by the energy conversion module (10) and/or outputting the stored electric energy to the energy conversion module (10).

5. The CT power supply and distribution device as recited in claim 4, wherein the energy storage module (13) comprises: an electrochemical energy storage unit (131) and an electromagnetic energy storage unit (132), wherein the electrochemical energy storage unit (131) is connected with the electromagnetic energy storage unit (132); wherein,

The electrochemical energy storage unit (131) is used for outputting electric energy to the energy conversion module (10) and/or the electromagnetic energy storage unit (132) at a first current multiplying power;

The electromagnetic energy storage unit (132) is used for outputting electric energy to the energy conversion module (10) at a second current multiplying power.

6. The CT power supply and distribution device as recited in claim 4, wherein the power distribution module (1) further comprises: the sensor group (14), the said sensor group (14) communicates with said energy storage module (13) and said energy management module (3) separately;

The sensor group (14) is used for detecting the working state of the energy storage module (13) and generating an electric signal.

7. The CT power supply and distribution device as recited in claim 1, wherein the energy management module (3) comprises: and the energy storage management unit (32), wherein the energy storage management unit (32) is respectively in communication connection with the power supply adaptation terminal (2) and the CT equipment (4).

8. The CT power supply and distribution device as recited in claim 1 or 7, wherein the energy management module (3) comprises: -a controller unit (31), the controller unit (31) being in communication connection with the energy management module (3) and the CT device (4), respectively.

9. A CT power supply and distribution system, comprising: CT apparatus (4) and switch board (5), CT apparatus (4) is connected with switch board (5), switch board (5) include the CT power supply and distribution device of any one of claims 1 to 8.

10. The CT power supply and distribution system as recited in claim 9, wherein the CT apparatus (4) comprises: a CT frame, a CT scanning support bed and a CT console.