JP2015204683A - Electronic device mounting stand and non-contact power transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve safety and to eliminate the need of work for inserting/pulling a power source side connection terminal of a power cord into/out of a receptacle in the case of move by eliminating the need of the power cord.SOLUTION: An electronic device mounting stand includes: a base part 11 which includes a plurality of legs 11b and is installed on a floor surface 4; a strut 12 which is erected in the base part 11 and configured to mount one or two or more electronic devices 51 thereto; and a power source part 13 capable of supplying actuation power to the electronic devices 51. The power source part 13 includes a power receiving coil 21 for receiving power transmitted from a power transmitting coil 42 which is installed on the floor surface 4, in a non-contact manner and the power received by the power receiving coil 21 can be converted into the actuation power and supplied to the electronic devices 51.

Description

  The present invention includes an electronic device mounting stand having a base portion placed on a floor surface and a support column erected on the base portion, and one or more electronic devices can be attached to the support column, and The present invention relates to a non-contact power transmission system including the electronic device mounting stand.

  As this type of electronic equipment mounting stand, a stand (infusion stand) disclosed in Patent Document 1 below is known. The stand includes a base portion (leg portion) having a plurality of legs, a support column provided on the base unit to which one or more infusion devices can be attached, and a liquid column provided on the support column. The liquid container holding part which can hold | maintain a container, and the multiple power supply structure which can supply power simultaneously with respect to the 1 or 2 or more infusion apparatus attached to the support | pillar are provided. In addition, as an example, this multiple power supply structure has one end extending as one cord from the lower end of the column to the outside of the column, and a power supply side connection terminal is attached to the tip of the cord, and other parts are provided inside the column. The end side is branched into a plurality of parts, and a plurality of branched tips extend outward from the outer peripheral surface of the support column, and are composed of a power cord with an infusion device connection terminal attached to each tip.

  In this stand, once the infusion device connection terminal is once connected to one or more infusion devices attached to the column, one power supply side connection provided at the tip of the power cord extending from the lower end of the column to the outside For example, the power is supplied to all infusion devices by simply inserting the terminal into an outlet provided on the wall of the room. Therefore, according to this stand, it is possible to operate the infusion device attached to the column by moving the stand to an arbitrary place only by performing the work of inserting and removing one power supply side connection terminal. Yes.

JP 2012-65846 A (Page 5-6, Fig. 1-2)

  However, the above-described stand has the following problems to be improved. In other words, this stand has a multiple power supply structure, so that the infusion device can be operated by moving the stand to an arbitrary place simply by inserting and removing one power supply side connection terminal. It has become. However, for example, in hospitals, it may be necessary for the patient to perform the work of plugging / unplugging the power supply side connection terminal from the outlet. However, there is a problem to be improved that there are times when this operation cannot be easily performed. Further, in this stand, although there is only one, there is a danger that the power cord is caught between the stand and the outlet because the power cord exists between the stand and the outlet.

  The present invention has been made to solve such a problem, and by eliminating the need for a power cord, safety can be improved, and work for connecting and disconnecting the power supply side connection terminal of the power cord from the outlet can be eliminated during movement. It is a main object of the present invention to provide an electronic device mounting stand and a non-contact power transmission system including the stand.

  In order to achieve the above object, an electronic equipment mounting stand according to claim 1 is provided with a base portion having a plurality of legs and placed on a floor surface, and one or two or more electronic devices standing on the base portion. An electronic device mounting stand including a support column configured to be capable of mounting a device and a power supply unit capable of supplying operating power to the electronic device, wherein the power supply unit is a power transmission installed on the floor surface A power receiving coil that receives the power transmitted from the coil in a non-contact manner is provided, and the power received by the power receiving coil is converted into the operating power and supplied to the electronic device.

  The electronic device mounting stand according to claim 2 is the electronic device mounting stand according to claim 1, wherein the power receiving coil is disposed at a portion of the base portion facing the floor surface.

  The electronic device mounting stand according to claim 3 is the electronic device mounting stand according to claim 1 or 2, wherein the power supply unit includes a storage battery that stores the electric power received by the power receiving coil, and stores the electric power in the storage battery. The electric power used is configured to be convertible into the operating power.

  The electronic device mounting stand according to claim 4 is the electronic device mounting stand according to any one of claims 1 to 3, wherein the power supply unit transmits the operating power to the electronic device in a contactless manner. It has a power transmission coil for electronic equipment.

  A non-contact power transmission system according to a fifth aspect includes the electronic device mounting stand according to any one of the first to fourth aspects and a power transmission device having the power transmission coil.

  Moreover, the non-contact power transmission system according to claim 6 is the non-contact power transmission system according to claim 5, wherein the power transmission coil is formed between the tip ends of a pair of adjacent legs of the plurality of legs. It is formed in the size which can enter below.

  The contactless power transmission system according to claim 7 is the contactless power transmission system according to claim 5 or 6, further comprising an electromagnetic shield plate laid on the floor surface, wherein the electromagnetic shield plate includes the plurality of electromagnetic shield plates. The tip of the leg is formed in a circular shape equivalent to a circle inscribed therein, and the power transmission coil is installed at the center of the surface of the electromagnetic shield plate.

  Further, in the non-contact power transmission system according to claim 8, in the non-contact power transmission system according to claim 7, the electromagnetic shield plate is formed such that the plate thickness of the peripheral portion is thicker than other portions.

  According to the electronic device mounting stand according to claim 1 and the non-contact power transmission system according to claim 5, the power source having the power receiving coil that receives the power transmitted from the power transmitting coil of the power transmitting device in a non-contact manner. Since the power cord for connecting the power supply unit to an outlet (external outlet) provided on the wall of the room or the like can be omitted, the electronic device is attached to the column and the electronic device Once the work of connecting the power connector to the output terminal of the power supply unit is carried out once, the electronic device mounting stand can be moved to the power supply position (the power transmission coil is installed) without any work of plugging the power plug into the outlet. The electric power for operation can be supplied to the electronic device simply by moving it to the position. In addition, since there is no power cord for connecting the power supply unit to an external outlet in the electronic device mounting stand, there is no danger of catching the power cord with your feet. According to the non-contact power transmission system, high safety can be ensured.

  According to the electronic device mounting stand according to claim 2 and the non-contact power transmission system according to claim 5, since the power receiving coil is disposed at a portion of the base portion of the electronic device mounting stand facing the floor surface, When the equipment mounting stand is moved to the power feeding position, this power receiving coil can be opposed to the power transmission coil installed on the floor surface, so that power can be efficiently transmitted from the power transmission device to the electronic equipment mounting stand. Can be done with.

  According to the electronic device mounting stand according to claim 3 and the non-contact power transmission system according to claim 5, the power supply unit includes a storage battery that stores the power received by the power receiving coil, and operates the power stored in the storage battery. Since the electronic device mounting stand is moved from the power feeding position to another position, the operation power can be continuously supplied to the electronic device because the electronic device mounting stand is moved from the power feeding position.

  According to the electronic device mounting stand according to claim 4 and the non-contact power transmission system according to claim 5, an electronic device having a built-in power receiving coil and capable of receiving power for operation in a non-contact manner is received on the electronic device side. The power supply for the electronic device can be made to receive electric power for operation from the electronic device mounting stand simply by performing the work of attaching to the column with the coil and the power transmission coil on the electronic device mounting stand side facing each other. The work of connecting the connector can also be omitted.

  According to the non-contact power transmission system according to claim 6, the power transmission coil is formed in such a size that it can enter the lower portion of the base portion from between the tips of a pair of adjacent legs of the plurality of legs of the electronic device mounting stand. Therefore, when the electronic device mounting stand is moved to the power feeding position, or when the electronic device mounting stand is moved from the power feeding position to another position, the tip of the leg and the power transmission coil temporarily contact each other. However, since this contact state can be eliminated by simply shifting the position of the base portion, the electronic device mounting stand can be moved to the power feeding position, and the electronic device mounting stand can be separated from the power feeding position. The movement to the position can be performed smoothly and easily.

  In the non-contact power transmission system according to claim 7, the electronic device mounting stand is formed in a circular shape having a size equivalent to a circle inscribed at the tip of each leg, and includes an electromagnetic shield plate laid on the floor surface, The power transmission coil is disposed at the center of the surface of the electromagnetic shield plate. Therefore, according to the non-contact power transmission system, the electromagnetic shield plate minimizes a decrease in the efficiency of power transmission to the power receiving coil of the electronic device mounting stand disposed above the power transmitting coil, and the power transmitting coil. The level of the electromagnetic field radiated from can be reduced. In addition, by placing a power transmission coil in the center of a circular electromagnetic shield plate equivalent to the circle inscribed at the tip of each leg, when moving the electronic device mounting stand to the power feeding position, the electromagnetic shield plate is used as a mark. By simply moving the electronic device mounting stand so that the base portion of the electronic device mounting stand is located within (including) the electromagnetic shield plate, the power receiving coil can be reliably and easily positioned in a state of facing the power transmitting coil.

  According to the non-contact power transmission system according to claim 8, the thickness (thickness) of the peripheral portion of the electromagnetic shield plate in which the power transmission coil is disposed is thicker than the other part (inner part) over the entire circumference. After the base part of the electronic device mounting stand has moved once on the electromagnetic shield plate (within its peripheral part), the peripheral part of the thick electromagnetic shield plate serves as a positioning guide. Even if a slight external force is applied to the electronic device mounting stand, it is possible to prevent the occurrence of a situation in which the base part is detached from the electromagnetic shield plate (moves to the outside of the electromagnetic shield plate). For this reason, according to this non-contact power transmission system, the power transmission device can more stably perform power transmission in a non-contact manner with respect to the electronic device mounting stand moved to the power feeding position.

It is a block diagram of the stand 2 and the non-contact electric power transmission system 1. It is a principal part front view of the base part 11 and the power transmission coil 42 in the state which moved the stand 2 to the electric power feeding position FP. 3 is a block diagram showing a configuration of a power supply unit 13 of the stand 2. FIG. It is a block diagram which shows the structure of the other power supply part. It is a block diagram of other stand 2A. It is a block diagram which shows the structure of the power supply part 13A in the stand 2A of FIG. It is a principal part perspective view which shows the state which attached the electronic device 51 to the mount 14 of the stand 2A of FIG. It is a top view for demonstrating the structure of the power transmission coil 42 of the power transmission apparatus 3 which provided the stands 2 and 2A which provided the electromagnetic shielding board 15, and the electromagnetic shielding board 45. FIG. FIG. 9 is a front view of essential parts of the stands 2 and 2A, the electromagnetic shield plate 45, and the power transmission coil 42 in a state in which the stands 2 and 2A of FIG. 8 are moved to the power feeding position FP. It is a top view of other electromagnetic shielding board 45A and the power transmission coil 42 mounted in the upper surface. 10 is a front view of essential parts of the stands 2 and 2A, the electromagnetic shield plate 45A and the power transmission coil 42 in a state where the stands 2 and 2A are moved onto the electromagnetic shield plate 45A of FIG. 10 (to the power feeding position FP). Is a cross-sectional view).

  Hereinafter, an electronic device mounting stand and an embodiment of a non-contact power transmission system including the electronic device mounting stand will be described with reference to the accompanying drawings.

  First, the configuration of the non-contact power transmission system 1 will be described with reference to the drawings.

  As shown in FIG. 1, the non-contact power transmission system 1 includes an electronic device mounting stand 2 (hereinafter also simply referred to as “stand 2”) and a power transmission device 3. In the non-contact power transmission system 1, power (high-frequency power) transmitted (transmitted) from a power transmission coil 42 (described later) of the power transmission device 3 that is also mounted on the floor surface 4 of the stand 2 mounted on the floor surface 4. ), And the received power is converted into operating power and can be supplied to the electronic device 51 attached to the stand 2. In this case, when the stand 2 is used in a hospital, medical devices such as an infusion pump, a syringe pump, a blood pressure monitor, a heart rate monitor, and an electrocardiograph are attached to the stand 2 as the electronic device 51.

  First, the configuration of the stand 2 will be described.

  As shown in FIG. 1, the stand 2 includes a base portion 11, a support column 12, and a power supply portion 13. The base portion 11 includes, as an example, a base 11a, a plurality of (in this example, five as an example) legs 11b, and the same number of casters 11c as the legs 11b. The base 11a is formed in a disk shape as an example in this example. Each leg 11b is formed in a long prismatic body as an example, and one end of each leg 11b is fixed to the outer peripheral surface of the base 11a so as to extend radially from the base 11a at equal angular intervals. ing. Each caster 11c is disposed on the lower surface (the surface facing the floor surface 4) of the other end of each leg 11b.

  Note that the base portion 11 is not limited to the above configuration, and the number of legs 11b may be set to an arbitrary number of three, four, or even six or more. The angular interval between the adjacent legs 11b of the portion is set to an angle different from the angular interval between the other adjacent legs 11b, the base 11a and each leg 11b are integrally formed, and the caster 11c is omitted. Various configurations can be employed.

  As shown in FIG. 1, the support column 12 is erected on the upper surface of the base portion 11, and is configured so that one or more electronic devices 51 can be attached thereto. In this example, as an example, the support column 12 is formed in one long cylindrical body, and is erected on the upper surface of the base 11 a so as to be orthogonal to the floor surface 4. Each electronic device 51 can be attached to an arbitrary position (an arbitrary height) of the support column 12 in an arbitrary direction by a fixture (not shown). In addition, the support column 12 includes a power source main unit 22 (to be described later) of the power source unit 13, a handle (not shown) that is held by a person when the stand 2 is moved, and various holders (for example, an infusion pack holder). Similarly to the electronic device 51, it is configured to be attachable to an arbitrary position and in an arbitrary direction by a fixture (not shown). In addition, the number of support | pillars 12 is not limited to one, You may make it two or more.

  As shown in FIGS. 1 and 3, the power supply unit 13 includes, as an example, a power receiving coil (power receiving coupler) 21, a power source main body 22 and an output terminal 23, and the power (high frequency) transmitted from the power transmitting device 3 by the power receiving coil 21. The power main body 22 converts the received power into operating power and supplies it to the electronic device 51 via the output terminal 23. Moreover, in the stand 2 of this example, as shown in FIG. 1, the structure which attaches the power supply main-body part 22 to the site | part of the lower end side in the support | pillar 12 is employ | adopted, However, The structure which mounts and mounts on the upper surface of the base part 11 Can also be adopted.

  An example of a specific configuration of the power supply unit 13 will be described with reference to FIGS. As shown in FIGS. 1 and 2, the power receiving coil 21 is arranged at a position facing the floor surface 4 in the base portion 11 so as to be separated from the floor surface 4 and parallel to the floor surface 4. In this example, since the outer shape of the power receiving coil 21 in plan view is larger than the outer shape of the base 11a constituting the base portion 11, the portion facing the floor surface 4 in the base portion 11 (the lower surface of the base 11a). And the lower surface of the base portion 11 formed by the lower surface of each leg 11b.

  In addition, the power receiving coil 21 is formed in any one of a circular shape, an elliptical shape, and a polygonal shape (in this example, a circular shape) in a plan view, and the central portion of the power receiving coil 21 is a base 11a (more specifically, in a plan view). Are positioned and arranged so as to coincide with the support columns 12) erected on the base 11a. In addition, the power receiving coil 21 is magnetically coupled to the power transmission coil in a state where the power receiving coil 21 is positioned in the vicinity of the power transmission coil of the power transmission device 3 installed on the floor surface 4, and is subjected to an electromagnetic induction method or a resonance (resonance) method. The power (high frequency power) from the power transmission device 3 is received in a non-contact manner.

  The power supply main body 22 includes an AC / DC power supply circuit 31, a charge / discharge circuit 32, a storage battery 33, and a power reception side control circuit 34. The AC / DC power supply circuit 31 converts the power (high frequency power) output from the power receiving coil 21 into a DC voltage within a preset voltage value range and outputs the DC voltage to the output line Lo. This voltage value range is determined based on the power supply specifications of the electronic device 51 that operates using the DC voltage output from the output terminal 23 as the operating power.

  The charging / discharging circuit 32 is disposed between the output line Lo and the storage battery 33 and is controlled by the power receiving side control circuit 34 so that the DC / DC voltage output from the AC / DC power supply circuit 31 to the output line Lo. Any one of a charging operation for charging the storage battery 33 based on this and a discharging operation for generating a DC voltage to the output line Lo based on the charging power (DC voltage) charged in the storage battery 33 and discharging the output line Lo to the output line Lo. Perform the action.

  The power receiving side control circuit 34 is, for example, a DC voltage output from the AC / DC power supply circuit 31 to the output line Lo and a charging voltage of the storage battery 33 (provided that the charging voltage value is equal to or higher than the lower limit charging voltage value). The charging / discharging circuit 32 is controlled while detecting the voltage value of the DC voltage of the output line Lo and the charging voltage value of the storage battery 33 by operating with the supply of a voltage having a high voltage value.

  As an example, the power receiving side control circuit 34 is configured such that the voltage value of the DC voltage of the output line Lo is within the voltage value range described above (for example, the voltage value range of the DC voltage of the output line Lo is set to + 20V to + 25V. If the charging voltage value of the storage battery 33 is less than the upper limit charging voltage value of the storage battery 33, the charging / discharging circuit 32 is controlled to execute the above charging operation. Thus, the storage battery 33 is charged. Further, when the charging voltage value of the storage battery 33 reaches the upper limit charging voltage value of the storage battery 33 during the charging, the power receiving side control circuit 34 controls the charging / discharging circuit 32 to stop the charging operation.

  In addition, the power receiving side control circuit 34 decreases the voltage value of the DC voltage of the output line Lo to a voltage less than the voltage value range described above, and the charging voltage value of the storage battery 33 is equal to or higher than the lower limit charging voltage value of the storage battery 33. In some cases, the charge / discharge circuit 32 is controlled to execute the above-described discharge operation, thereby preventing the voltage value of the DC voltage in the output line Lo from decreasing (increasing or reducing the degree of decrease). As a result, even when the power output from the power receiving coil 21 to the power source main body 22 is stopped or reduced, the voltage value of the DC voltage of the output line Lo is kept within a voltage value range defined in advance for a longer time. In other words, the electronic device 51 to which the DC voltage of the output line Lo is supplied as operating power via the output terminal 23 can be operated for a longer time. In addition, when the charge voltage value of the storage battery 33 reaches the lower limit charge voltage value during the discharge of the storage battery 33, the power reception side control circuit 34 controls the charge / discharge circuit 32 to stop the discharge operation, thereby overdischarge. It is possible to prevent.

  For example, as shown in FIG. 1, the output terminal 23 has a structure in which connectors 23 a to which a power connector 52 attached to the tip of a power cable of the electronic device 51 can be connected are arranged in the same housing. However, it is not limited to this structure. For example, although not shown, the output terminal 23 can be configured by a plurality of connectors 23a connected to the ends of a plurality of power cables branched from the output line Lo.

  The power supply main body 22 includes an AC / DC power supply circuit 31 and connects a DC voltage output from the AC / DC power supply circuit 31 to the output terminal 23 via the output line Lo and the output terminal 23. Although the configuration for supplying the electronic device 51 as operating power to the electronic device 51 is employed, a configuration for supplying an AC voltage to the electronic device 51 as operating power can also be employed.

  For example, as shown in FIG. 4, a DC / AC power supply circuit 35 is connected to the output line Lo, and the DC / AC power supply circuit 35 converts the DC voltage output from the AC / DC power supply circuit 31 to the output line Lo to AC. While converting into voltage, this alternating voltage is output to the other output line Lo1 to which the output terminal 23 is connected, whereby the alternating voltage is supplied to the electronic device 51 connected to the output terminal 23 as operating power. A configuration can also be adopted. In this case, the DC / AC power supply circuit 35 converts the DC voltage of the output line Lo into, for example, AC 100V and outputs it to the output line Lo1. As a result, the electronic device 51 using the commercial power source (AC voltage) as the operating power can be attached to the stand 2 for use.

  Further, by adopting a configuration including both power supply main body portions 22 shown in FIGS. 3 and 4, a DC voltage is supplied as operating power from a predetermined output terminal 23, and an AC voltage is supplied from the other output terminals 23. Can be supplied as operating power, so that both the electronic device 51 that uses DC voltage as operating power and the electronic device 51 that uses commercial power (AC voltage) as operating power are attached to the stand 2 and used. It becomes possible to do.

  Next, the configuration of the power transmission device 3 will be described.

  As shown in FIG. 1, the power transmission device 3 includes a high frequency power supply circuit 41, a power transmission coil (power transmission coupler) 42, a stand detection sensor 43, and a power transmission side control circuit 44. The high frequency power supply circuit 41 is controlled by the power transmission side control circuit 44 to generate high frequency power having a frequency of about 1 MHz to several tens of MHz as an example based on a commercial power supply (AC voltage), for example, Output to 42.

  As shown in FIG. 1, the power transmission coil 42 is entirely covered with a protective film made of synthetic resin, etc., and the entire shape including the protective film is formed into a thin plate shape (for example, a maximum of several tens of millimeters). Then, it is installed (fixed) at a site set at the power feeding position FP (see FIG. 2) on the floor surface 4. The power transmission coil 42 is formed in any one of a circular shape, an elliptical shape, and a polygonal shape in plan view, and the maximum size of the outer shape is a pair of adjacent legs among the plurality of legs 11b of the stand 2. It is formed in such a size that it can enter below the base portion 11 from between the tips of 11b (specifically, between a pair of casters 11c attached to the tips of the pair of legs 11b).

  In this example, as shown in FIG. 1, the power transmission coil 42 has a pair of legs whose planar shape is formed in a circular shape as an example and whose size (maximum width; in this example, the diameter L1 is circular). The distance between the distal ends of the pair of legs 11b (specifically, the distance L2 between the distal ends of the pair of legs 11b (specifically, the distance between the pair of casters 11c attached to the distal ends of the pair of legs 11b)) Specifically, it is configured to be able to enter below the base portion 11 from between a pair of casters 11c attached to the tips of the pair of legs 11b.

  Moreover, in this example, since each leg 11b is a structure which extends radially and equiangularly from the base 11a as described above, the power transmission coil 42 is any of the plurality of legs 11b. It is possible to enter the lower part of the base portion 11 from between the tips of the adjacent pair of legs 11b (specifically, between any adjacent pair of casters 11c). In the configuration in which the angular interval of some adjacent legs 11b is set to an angle different from the angular interval between other adjacent legs 11b, the distance between the tips of a pair of adjacent legs 11b with the smallest angle (specifically Specifically, it is most preferable to configure the power transmission coil 42 to have a size capable of entering the lower portion of the base portion 11 from between the pair of casters 11c attached to the pair of legs 11b. What is necessary is just to be comprised by the magnitude | size which can approach below the base part 11 from between the front-end | tips of a pair of leg 11b (specifically between this pair of adjacent pair of casters 11c).

  The stand detection sensor 43 is composed of a sensor that can detect the presence or absence of an object such as a proximity switch, for example, and the base portion 11 of the stand 2 is located within a predetermined range centered on the stand detection sensor 43 ( Preferably, when the power transmission coil 42 enters below the base portion 11), the base portion 11 is detected and a detection signal is output to the power transmission side control circuit 44.

  For example, the power transmission side control circuit 44 operates by receiving supply of commercial power (alternating voltage), and executes control on the high-frequency power circuit 41 based on whether or not a detection signal is output from the stand detection sensor 43. Specifically, the power transmission side control circuit 44 is positioned when a detection signal is output from the stand detection sensor 43 (that is, the base portion 11 of the stand 2 is located within a predetermined range centering on the stand detection sensor 43). When the detection signal is not output from the stand detection sensor 43 (that is, the high frequency power supply circuit 41 is caused to generate high frequency power and output to the power transmission coil 42). When the base portion 11 of the stand 2 is located outside a predetermined range centered on the stand detection sensor 43), control is performed to stop the high-frequency power circuit 41 from generating high-frequency power.

  Subsequently, the operation of the non-contact power transmission system 1 will be described together with the operation of the stand 2 with reference to the drawings. One or more electronic devices 51 are attached in advance to the support column 12 of the stand 2, and the power connector 52 is connected to the output terminal 23 (specifically, the connector 23 a) of the power supply unit 13. Shall. Further, an example in which the stand 2 is used in a hospital as an infusion stand will be described. For this reason, an infusion pump and a syringe pump (in this example, a syringe pump) are attached to the stand 2 as the electronic device 51. Moreover, the storage battery 33 provided in the power supply main-body part 22 of the stand 2 assumes that the charging voltage value is less than a minimum charging voltage value.

  First, as shown in FIG. 1, when the stand 2 is located at a position shifted from the power feeding position FP, the stand detection sensor 43 does not detect the base portion 11 of the stand 2 in the power transmission device 3. For this reason, since the stand detection sensor 43 stops outputting the detection signal, the power transmission side control circuit 44 executes control for causing the high frequency power supply circuit 41 to stop generating high frequency power. Therefore, in this state, power transmission from the power transmission device 3 to the stand 2 is not performed.

  Moreover, in the stand 2, since the charging voltage value of the storage battery 33 is less than the lower limit charging voltage value, the power receiving side control circuit 34 is in a stopped state. Therefore, the charging operation and the discharging operation by the charging / discharging circuit 32 are stopped.

  Next, when the stand 2 is moved in the direction indicated by the arrow in FIG. 1 (the feeding position FP direction) by the patient, it can enter below the base portion 11 from between the tips of a pair of adjacent legs 11b of the base portion 11. Since the power transmission coil 42 is configured in a large size, the patient does not perform the act of tilting the stand 2 and lifting the caster 11c located on the power transmission coil 42 side, so that the power transmission coil 42 is connected to the pair of legs 11b adjacent to each other. It enters below the base part 11 from between the front ends. Thereby, the patient can move the stand 2 to the feeding position FP very easily as shown in FIG. When the stand 2 is located at the power feeding position FP, the power receiving coil 21 attached to the base portion 11 faces the power transmitting coil 42 installed on the floor surface 4 as shown in FIG.

  When the power transmission coil 42 enters below the base portion 11, the base portion 11 of the stand 2 is in a state of being located within a predetermined range centered on the stand detection sensor 43. For this reason, in the power transmission device 3, the stand detection sensor 43 detects the base unit 11 and outputs a detection signal to the power transmission side control circuit 44. In addition, the power transmission side control circuit 44 inputs the detection signal, thereby causing the high frequency power supply circuit 41 to generate high frequency power and control the power transmission coil 42 to output it. In this way, the power transmission device 3 detects the movement of the stand 2 to the power feeding position FP, and automatically starts outputting power from the power transmission coil 42.

  In the stand 2, the power receiving coil 21 that is opposed to the power transmitting coil 42 receives the high-frequency power from the power transmitting coil 42 in a non-contact manner in an efficient state and outputs the power to the power source main body 22. In the power supply main body 22, the AC / DC power supply circuit 31 converts the power (high-frequency power) output from the power receiving coil 21 into a DC voltage (a DC voltage within the above-described voltage value range) and outputs an output line Lo. Output to. As a result, a DC voltage is supplied as operating power to each electronic device 51 connected to the output terminal 23 via the output line Lo and the output terminal 23. Therefore, according to the stand 2, a power cord for connecting the power supply unit 13 to an outlet provided on, for example, a wall of a house can be eliminated, so that a power plug (power-side connection terminal) is used as an outlet. The operation power can be supplied to each electronic device 51 without performing the insertion work, and each electronic device 51 can be shifted to the operating state.

  The power receiving side control circuit 34 is also operated by receiving the supply of the DC voltage, and controls the charge / discharge circuit 32 while detecting the voltage value of the DC voltage of the output line Lo and the charge voltage value of the storage battery 33. Run.

  In this case, since the charging voltage value of the storage battery 33 is less than the lower limit charging voltage value as described above at the beginning when the power receiving coil 21 starts receiving power from the power transmission coil 42, the power receiving side control circuit 34 The storage battery 33 is charged by controlling the discharge circuit 32 to execute the charging operation. Further, when the charging voltage value of the storage battery 33 reaches the upper limit charging voltage value of the storage battery 33 during the charging, the power receiving side control circuit 34 controls the charging / discharging circuit 32 to stop the charging operation.

  Subsequently, when the stand 2 is moved from the power feeding position FP to another position by the patient, contrary to when the stand 2 is moved to the power feeding position FP, between the distal ends of the pair of legs 11b adjacent to the power transmission coil 42. It retreats from the lower part of the base part 11 via (between a pair of casters 11c attached to this pair of legs 11b). At this time, the patient can feed power to the stand 2 very easily without tilting the stand 2 and removing the power plug from the outlet in the same manner as when moving the stand 2 to the power feeding position FP. The position FP can be moved to another position.

  Further, when the base portion 11 of the stand 2 is gradually moving out of the predetermined range centered on the stand detection sensor 43, the coupling state of the power transmitting coil 42 and the power receiving coil 21 is gradually increased. become weak. For this reason, the power received by the power receiving coil 21 gradually decreases, and accordingly, the voltage value of the DC voltage output from the AC / DC power supply circuit 31 to the output line Lo also gradually decreases. In this case, when the voltage value of the DC voltage falls below the voltage value range described above, the power receiving side control circuit 34 receives the supply of the charging voltage from the storage battery 33 instead of the DC voltage from the output line Lo. Continue operation.

  Further, the power receiving side control circuit 34 is such that the voltage value of the DC voltage of the output line Lo becomes a voltage less than the voltage value range described above, and the charging voltage value of the storage battery 33 is equal to or higher than the lower limit charging voltage value of the storage battery 33. Therefore, the charging / discharging circuit 32 is controlled to execute the discharging operation. As a result, even if the supply of power from the AC / DC power supply circuit 31 to the output line Lo gradually decreases to zero, the charge / discharge circuit 32 is caused by the DC voltage generated based on the charge voltage of the storage battery 33. In this way, it is possible to prevent the voltage value of the DC voltage supplied from the output line Lo via the output terminal 23 to each electronic device 51 as operating power. Although the charging voltage value of the storage battery 33 gradually decreases with this discharging operation, the power receiving side control circuit 34 detects this charging voltage value, and until this charging voltage value becomes a voltage less than the voltage value range, Continue discharging. Therefore, even if the stand 2 is located at a position different from the power supply position FP, the stand 2 is normally operated for each electronic device 51 until the charging voltage value of the storage battery 33 becomes a voltage less than the voltage value range. It is possible to continue supplying power.

  On the other hand, in the power transmission device 3, the stand detection sensor 43 detects the detection signal when the base portion 11 of the stand 2 is out of a predetermined range centered on the stand detection sensor 43 (when the stand 2 moves from the power feeding position FP). Stop the output of. For this reason, the power transmission side control circuit 44 executes control for causing the high frequency power supply circuit 41 to stop generating high frequency power. In this way, the power transmission device 3 detects the movement of the stand 2 from the power feeding position FP, and automatically stops the output of power from the power transmission coil 42.

  Thus, according to the non-contact power transmission system 1 and the stand 2, the stand 2 includes the power supply unit 13 having the power receiving coil 21 that receives the power transmitted from the power transmission coil 42 of the power transmission device 3 in a non-contact manner. Therefore, since the power cord for connecting the power supply unit 13 to an outlet (external outlet) provided on the wall of the room can be omitted, the electronic device 51 is attached to the column 12 and the power source of the electronic device 51 is Once the operation of connecting the connector 52 to the output terminal 23 of the power supply unit 13 is performed once, thereafter, the stand 2 is moved to the power feeding position FP (the power transmission coil 42) without any work of inserting the power plug into the outlet. The electric power for operation can be supplied to the electronic device 51 simply by moving to the position where the electronic device 51 is installed. Further, since there is no power cord for connecting the power supply unit 13 to an external outlet in the stand 2, there is no danger of catching the power cord with a foot, and thus the non-contact power transmission system 1. And according to the stand 2, high safety | security can be ensured.

  Further, according to the non-contact power transmission system 1 and the stand 2, since the power receiving coil 21 is disposed at a portion of the base portion 11 of the stand 2 that faces the floor surface 4, the stand 2 moves to the power feeding position FP. When this is done, the power receiving coil 21 can be opposed to the power transmission coil 42 installed on the floor surface 4 in close proximity, so that power can be transmitted from the power transmission device 3 to the stand 2 in an efficient state. .

  In addition, according to the non-contact power transmission system 1 and the stand 2, the power supply unit 13 includes the storage battery 33 that stores the power received by the power receiving coil 21, and the power stored in the storage battery 33 can be converted into operating power. Therefore, even when the stand 2 is moved from the power feeding position FP to another position, it is possible to continue supplying the operating power to the electronic device 51. When the electronic device 51 itself attached to the support column 12 has a built-in storage battery, the electronic device 51 itself is connected via the output line Lo and the output terminal 23 in a state where the stand 2 is located at the power feeding position FP. The operation power can be stored in its own storage battery, and thus the operation state can be maintained with the operation power stored in its own storage battery when the stand 2 moves from the feeding position FP to another position. . Therefore, when the electronic device 51 itself has a built-in storage battery, the power supply unit 13 can be configured without the charge / discharge circuit 32 and the storage battery 33.

  Moreover, according to this non-contact electric power transmission system 1, between the front-end | tips of a pair of adjacent legs 11b among the several legs 11b of the stand 2 (specifically, between a pair of casters 11c attached to each front-end | tip) ), The power transmission coil 42 is formed in such a size that it can enter the lower part of the base portion 11, so that the stand 2 is moved to the power feeding position FP, or the stand 2 is moved from the power feeding position FP to another position. In this case, even if the tip of the leg 11b (specifically, the caster 11c attached to the tip) and the power transmission coil 42 are temporarily in contact with each other, an operation of slightly shifting the position of the base portion 11 is performed. Since this contact state can be eliminated, the movement of the stand 2 to the power feeding position FP and the movement of the stand 2 from the power feeding position FP to another position are smooth and easy. It can be carried out.

  In the non-contact power transmission system 1 described above, the operation of connecting the power connector 52 of the electronic device 51 to the output terminal 23 of the power supply unit 13 is required when the electronic device 51 is attached to the support 12. As shown in the stand 2A shown in FIG. 5, the power supply connector 52 can be connected to the output terminal 23 when the electronic device 51 is attached to the support column 12 by supplying electric power to the electronic device 51 without contact. It is possible to omit the work of connecting (the work equivalent to inserting the power plug into the outlet). Hereinafter, the stand 2A will be described. In addition, about the structure same as the stand 2, the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted. The stand 2 </ b> A is supplied with electric power from the power transmission device 3 in a non-contact manner in the same manner as the stand 2.

  As shown in FIG. 5, the stand 2 </ b> A includes a base part 11, a support column 12, a power supply part 13 </ b> A, and a mounting base 14, and the configuration other than the power supply part 13 </ b> A and the mounting base 14 is the same as that of the stand 2.

  As shown in FIGS. 5 and 6, the power supply unit 13 </ b> A includes, for example, a power reception coil 21, a power supply main body 22 </ b> A, and one or more power transmission coils 24 for electronic devices (hereinafter also referred to as “power transmission coil 24”). The power receiving coil 21 receives the power (high-frequency power) transmitted from the power transmitting device 3 in a non-contact manner, and the power source main body 22A converts the received power into operating power and the electronic device 51 via the power transmitting coil 24. Supplied without contact.

  Specifically, as shown in FIGS. 5 and 6, the power supply unit 13 </ b> A includes a power transmission coil 24 instead of the output terminal 23 of the power supply unit 13 shown in FIG. 3. Further, as shown in FIGS. 5 and 6, the power supply main unit 22A of the power supply unit 13A includes a high frequency power supply circuit 36 in addition to the configuration of the power supply main unit 22 shown in FIG. The high frequency power supply circuit 36 is connected to the output line Lo, converts the DC voltage output from the AC / DC power supply circuit 31 to the output line Lo into high frequency power (specifically, high frequency voltage), and the power transmission coil 24 This high-frequency power is configured to be output to another connected output line Lo2.

  The mounting base 14 is installed in advance on the support column 12 by the number corresponding to the number of electronic devices 51 to be installed. The mounting base 14 incorporates the above-described power transmission coil 24 of the power supply unit 13A.

  According to this stand 2A, as shown in FIG. 7, an electronic device 51 that includes a power receiving coil 53 as shown in FIG. 5 (with built-in power receiving coil 53) and can receive power for operation in a non-contact manner, The electronic device can receive electric power for operation from the stand 2 only by performing an operation of attaching to the support column 12 (specifically, the mounting base 14) in a state where the power receiving coil 53 and the power transmitting coil 24 face each other. 51 can be attached to the support column 12, so that the work of connecting the power connector 52 of the electronic device 51 to the output terminal 23 (the work equivalent to the work of plugging the power plug into the outlet) as compared with the stand 2 described above. Can also be omitted.

  Further, in this non-contact power transmission system 1, the power transmission device 3 automatically detects the movement of the stands 2 and 2A to the power feeding position FP and starts outputting power from the power transmission coil 42. By adopting a configuration in which the movement from the power feeding position FP of 2A to another position is automatically detected and the output of power from the power transmission coil 42 is stopped, that is, the power receiving coil 21 of the stand 2 or 2A is replaced with the power transmission coil. By adopting a configuration in which power is output from the power transmission coil 42 only when facing the power supply 42 and output of power from the power transmission coil 42 is stopped at other times, the radiated electromagnetic field is constantly generated from the power transmission coil 42. The situation of occurrence is avoided, and adverse effects on the human body due to the radiated electromagnetic field are reduced to a level at which no problem occurs.

  However, in order to reduce the radiated electromagnetic field from the power transmission coil 42 to a lower level, it is preferable to employ a configuration in which the electromagnetic shield plate 45 is provided in the power transmission coil 42, and further, the electromagnetic shield plate is also provided on the power receiving coil 21 side. It is more preferable to employ a configuration in which 15 is provided.

  The non-contact power transmission system 1 and the stands 2 and 2A provided with the electromagnetic shield plates 15 and 45 will be described with reference to FIGS.

  As shown in FIGS. 8 and 9, the stands 2 and 2 </ b> A include an electromagnetic shield plate 15 having a shape in plan view larger than that of the power receiving coil 21, and the electromagnetic shield plate 15 is a floor surface 4 in the base portion 11. The power receiving coil 21 is disposed at a portion facing the floor surface 4 of the electromagnetic shield plate 15. The power receiving coil 21 is arranged in a state of being hidden by the electromagnetic shield plate 15 in a plan view.

  On the other hand, the power transmission device 3 includes an electromagnetic shield plate 45, and the electromagnetic shield plate 45 is laid at the power feeding position FP on the floor surface 4. The electromagnetic shield plate 45 is a thin and uniform flat plate body on which the caster 11c of the stand 2 can easily ride. The electromagnetic shield plate 45 is arranged at the tip of each leg 11b of the stand 2 (specifically, the tip is arranged at this tip). It is formed in a circular shape having a size equivalent to a circle (virtual circle) CI in which each caster 11c provided and the floor 4 is inscribed. The power transmission coil 42 is disposed at the center of the surface of the electromagnetic shield plate 45.

  Therefore, according to the non-contact power transmission system 1, the electromagnetic shield plate 45 larger than the power transmission coil 42 is disposed (laid) immediately below the power transmission coil 42 in the power transmission device 3, so that it is disposed above the power transmission coil 42. The level of the radiated electromagnetic field from the power transmission coil 42 can be further reduced while minimizing the reduction in the efficiency of power transmission to the power reception coil 21 of the stand 2 to be performed. Further, since the outer shape of the electromagnetic shield plate 45 is formed in a circular shape equivalent to the circle CI, when the stand 2 is moved to the power feeding position FP, the electromagnetic shield plate 45 is used as a mark, and the base portion of the stand 2 is used. The power receiving coil 21 can be reliably and easily positioned in a state of facing the power transmitting coil 42 simply by moving the coil 11 so as to be positioned (included) in the electromagnetic shield plate 45.

  Furthermore, according to the non-contact power transmission system 1 and the stand 2, the electromagnetic shield plate 15 is also disposed immediately above the power receiving coil 21 disposed on the base portion 11 of the stand 2. The level of the radiated electromagnetic field can be further reduced.

  Further, the structure of the electromagnetic shield plate of the power transmission device 3 is not limited to the structure of the electromagnetic shield plate 45 described above, and for example, a structure such as an electromagnetic shield plate 45A shown in FIGS. Unlike the electromagnetic shield plate 45 having a uniform thickness, the electromagnetic shield plate 45A has a plate thickness (thickness) of the peripheral portion ED that is thicker than other parts (inner parts) over the entire circumference (wall). Thick). In this case, the thickness of the peripheral edge ED is such that, when the stand 2 is moved while being pushed to some extent, the caster 11c can easily get over, but after the stand 2 moves to the power feeding position FP, After all the casters 11c have moved into the peripheral edge ED, the casters 11c are formed to a thickness that cannot easily get over the peripheral edge ED when the stand 2 is lightly pressed.

  Therefore, in this non-contact power transmission system 1, after the base portion 11 of the stand 2 has moved once on the electromagnetic shield plate 45A (inside the peripheral edge ED), the peripheral edge ED of the electromagnetic shield plate 45A formed to be thick. However, even if a slight external force is applied to the stand 2, it is possible to prevent the occurrence of a situation in which the base portion 11 is detached from the electromagnetic shield plate 45 </ b> A (moves to the outside of the electromagnetic shield plate 45 </ b> A). For this reason, according to this non-contact electric power transmission system 1, the power transmission apparatus 3 can perform electric power transmission more contactlessly with respect to the stand 2 which moved to the electric power feeding position FP.

  In the non-contact power transmission system 1, the power transmission device 3 includes a proximity switch as an example of the stand detection sensor 43, moves the stands 2 and 2 </ b> A to the feeding position FP, and feeds the stands 2 and 2 </ b> A. Although the structure which detects automatically the movement from FP to another position is employ | adopted, the power transmission apparatus 3 carries out the electric power feeding of the stands 2 and 2A because the stands 2 and 2A and the power transmission apparatus 3 perform wireless communication. It is also possible to automatically detect the movement to the position FP and the movement of the stands 2 and 2A from the power feeding position FP to another position. For example, by adopting a configuration in which a tag is provided on the stand 2 or 2A side and a reader is provided as a stand detection sensor 43 on the power transmission device 3, the RFID (radio frequency identifier) technology is employed. Can be realized.

1 Non-contact power transmission system
2 Stand
3 Power transmission equipment
4 Floor 11 Base 11b Leg 12 Support 13 Power Supply 21 Power Receiving Coil 42 Power Transmitting Coil 51 Electronic Device

Claims (8)

A base portion that has a plurality of legs and is placed on the floor surface, a support that is erected on the base portion and that can be attached with one or more electronic devices, and for operating the electronic device An electronic device mounting stand including a power supply unit capable of supplying power,
The power supply unit includes a power receiving coil that receives power transmitted from a power transmitting coil installed on the floor surface in a contactless manner, converts the power received by the power receiving coil into the operating power, and converts the power into the electronic device. Electronic equipment mounting stand that can be supplied to.   The electronic device mounting stand according to claim 1, wherein the power receiving coil is disposed at a portion of the base portion facing the floor surface.   3. The electronic device according to claim 1, wherein the power supply unit includes a storage battery that stores the power received by the power receiving coil, and is configured to be able to convert the power stored in the storage battery into the operating power. Equipment mounting stand.   The electronic device mounting stand according to any one of claims 1 to 3, wherein the power supply unit includes an electronic device power transmission coil for transmitting the operating power to the electronic device in a contactless manner.   A non-contact power transmission system comprising the electronic device mounting stand according to claim 1 and a power transmission device having the power transmission coil.   The non-contact power transmission system according to claim 5, wherein the power transmission coil is formed to have a size capable of entering the lower portion of the base portion from between the tips of a pair of adjacent legs among the plurality of legs. Comprising an electromagnetic shielding plate laid on the floor,
The electromagnetic shield plate is formed in a circular shape equivalent to a circle inscribed with the tips of the plurality of legs,
The contactless power transmission system according to claim 5 or 6, wherein the power transmission coil is installed at a center of the surface of the electromagnetic shield plate.   The non-contact power transmission system according to claim 7, wherein the electromagnetic shield plate is formed such that the thickness of the peripheral portion is thicker than other portions.

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