(19)
(11)EP 3 925 644 B1

(12)EUROPEAN PATENT SPECIFICATION

(45)Mention of the grant of the patent:
24.01.2024 Bulletin 2024/04

(21)Application number: 20778434.9

(22)Date of filing:  26.02.2020
(51)International Patent Classification (IPC): 
G06F 1/32(2019.01)
A61M 5/142(2006.01)
(52)Cooperative Patent Classification (CPC):
A61M 5/142; G06F 1/32
(86)International application number:
PCT/JP2020/007771
(87)International publication number:
WO 2020/195489 (01.10.2020 Gazette  2020/40)

(54)

POWER SUPPLY CONTROL CIRCUIT, AND MEDICAL LIQUID ADMINISTRATION DEVICE COMPRISING SAID POWER SUPPLY CONTROL CIRCUIT

STROMVERSORGUNGSSTEUERSCHALTUNG UND MEDIZINISCHE FLÜSSIGKEITSVERABREICHUNGSVORRICHTUNG MIT DIESER STROMVERSORGUNGSSTEUERSCHALTUNG

CIRCUIT DE COMMANDE D'ALIMENTATION ÉLECTRIQUE, ET DISPOSITIF D'ADMINISTRATION DE LIQUIDE MÉDICAL COMPRENANT LEDIT CIRCUIT DE COMMANDE D'ALIMENTATION ÉLECTRIQUE


(84)Designated Contracting States:
AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR

(30)Priority: 28.03.2019 JP 2019064560

(43)Date of publication of application:
22.12.2021 Bulletin 2021/51

(73)Proprietor: TERUMO Kabushiki Kaisha
Tokyo 151-0072 (JP)

(72)Inventor:
  • YAKUSHIJI,Yusuke
    Ashigarakami-gun, Kanagawa 259-0151 (JP)

(74)Representative: Casalonga 
Casalonga & Partners Bayerstraße 71/73
80335 München
80335 München (DE)


(56)References cited: : 
JP-A- H05 265 599
JP-A- H10 240 392
US-A1- 2009 153 236
JP-A- H05 265 599
JP-A- 2015 128 336
  
      
    Note: Within nine months from the publication of the mention of the grant of the European patent, any person may give notice to the European Patent Office of opposition to the European patent granted. Notice of opposition shall be filed in a written reasoned statement. It shall not be deemed to have been filed until the opposition fee has been paid. (Art. 99(1) European Patent Convention).


    Description

    Technical Field



    [0001] The present invention relates to a power supply control circuit capable of achieving power saving and a drug solution administration apparatus including the power supply control circuit. JP H05 265599 A discloses a battery power supply control circuit in an electronic apparatus controlled by a microcomputer. A momentary switch connects the battery supply to the microcomputer which outputs a signal to an energization circuit, comprising an npn transistor, which turns on a P-channel MOSFET semiconductor switching element, which bypasses the momentary switch.

    Background Art



    [0002] Conventionally, there have been known syringe pump type drug solution administration apparatuses for administering a drug solution filled in a drug solution container to a living body, such as the one disclosed in Patent Literature 1. A syringe pump type drug solution administration apparatus includes a power source, a microcomputer, and a drive device, and is capable of continuously administering a drug solution with high precision over a long period of time with the drive device causing a pusher to move little by little.

    [0003] This type of drug solution administration apparatus may be stored under refrigeration without being powered on for a long time on the order of years (for example, for several years) after manufactured in a factory until used in a hospital or the like. When the power switch of the drug solution administration apparatus is turned on immediately before use, an electrical closed circuit including a battery is formed so that a drug solution can be administered.

    Citation List


    Patent Literature



    [0004] Patent Literature 1: JP 2015-181869 A

    Summary of Invention


    Technical Problem



    [0005] The size of a drug solution administration apparatus is minimized for purposes including achieving easier handling when the apparatus is in use and storage-space saving when the apparatus is stored. For this reason, a small-sized button battery is employed as the power source. In addition, the microcomputer is provided with a protection circuit so that the microcomputer is not damaged by noise.

    [0006]  During the storage under refrigeration, the main power is not supplied to the microcomputer in the drug solution administration apparatus because the power switch is not turned on, although a button battery stays inserted in the apparatus. However, during the storage under refrigeration, a leakage current flows through the protection circuit to consume the power of the button battery. In a case where the drug solution administration apparatus is stored under refrigeration for a long time, the leakage current reduces the capacity of the button battery, with the result that the drug solution administration apparatus in actual use may fail to administer the full amount of the drug solution to the user because of the insufficient capacity. A solution to avoiding such situation is to increase the capacity of the button battery in anticipation of the consumption caused by the leakage current, but such solution cannot be selected because the solution hinders reduction in size and cost of the drug solution administration apparatus.

    [0007] Therefore, an object of the present invention is to provide a power supply control circuit capable of achieving power saving and a drug solution administration apparatus including the power supply control circuit.

    Solution to Problem



    [0008] This object is achieved by a power supply control circuit according to independent claim 1 and a drug solution administration apparatus according to claim 7. The dependent claims relate to advantageous embodiments.

    Advantageous Effects of Invention



    [0009] The power supply control circuit and the drug solution administration apparatus including the power supply control circuit according to the present invention can achieve power saving during storage before the apparatus is powered on because the leakage circuit can be cut off. In addition, reduction in size and cost of the drug solution administration apparatus can be achieved.

    Brief Description of Drawings



    [0010] 

    Fig. 1 is a side view of a drug solution administration system.

    Fig. 2 is a diagram schematically illustrating a usage example of the drug solution administration system.

    Fig. 3 is a schematic perspective view of the drug solution administration apparatus.

    Fig. 4 is a schematic perspective view of a chassis included in a housing and of individual components assembled to the chassis.

    Fig. 5 is a plan view of the drug solution administration apparatus in a state where a pusher is not moved forward yet.

    Fig. 6 is a plan view of the drug solution administration apparatus in a state where the pusher has been moved forward.

    Fig. 7 is a block diagram of a power supply control circuit included in a control unit.

    Fig. 8 is an operation flowchart for the drug solution administration apparatus.

    Fig. 9 is a diagram for explaining operations of the power supply control circuit.

    Fig. 10 is a block diagram of a power supply control circuit included in a conventional control unit.

    Fig. 11 is a diagram for explaining operations of a conventional power supply control circuit.


    Description of Embodiments



    [0011] Embodiments of the present invention will now be described with reference to the accompanying drawings. Note that the following description does not limit the technical scope or meaning of terms described in the claims. In addition, dimensional ratios in the drawings are exaggerated for convenience of description and may be different from actual ratios.

    [0012] Figs. 1 to 6 are diagrams for explaining a drug solution administration system 10, a drug solution administration apparatus 100, and an administration instrument 200 according to the present embodiment. Fig. 1 is a side view of the drug solution administration system. Fig. 2 is a diagram schematically illustrating a usage example of the drug solution administration system. Fig. 3 is a schematic perspective view of the drug solution administration apparatus. Fig. 4 is a schematic perspective view of a chassis included in a housing and of individual components assembled to the chassis. Fig. 5 is a plan view of the drug solution administration apparatus in a state where a pusher is not moved forward yet. Fig. 6 is a plan view of the drug solution administration apparatus in a state where the pusher has been moved forward. In the drawings, an arrow X indicates the "longitudinal direction (longitudinal direction of a drug solution container 110)" of the drug solution administration apparatus 100, an arrow Y indicates the "width direction (depth direction)" of the drug solution administration apparatus 100, and an arrow Z indicates the "height direction" of the drug solution administration apparatus 100.

    (Drug solution administration system)



    [0013] The drug solution administration system 10 is used for administering a drug solution into a living body. As illustrated in Fig. 1, the drug solution administration system 10 includes a drug solution administration apparatus 100 and an administration instrument 200.

    [0014] As illustrated in Fig. 2, the drug solution administration apparatus 100 and the administration instrument 200 are configured as patch-type devices to be attached to a body surface (skin) H of the user before use. The site of the user body to which the drug solution administration apparatus 100 and the administration instrument 200 are attached is not particularly limited, and examples thereof include the abdomen and thighs.

    [0015] The drug solution administration system 10 is capable of continuously administering a drug solution (not illustrated) filled in a drug solution container 110 included in the drug solution administration apparatus 100 into a living body over a relatively long period of time (for example, about several minutes to several hours) by a pressing action provided by a pusher 130, which will be described later (see Fig. 4). Note that the drug solution administration system 10 may intermittently administer a drug solution into a living body.

    (Drug solution administration Apparatus)



    [0016] As illustrated in Figs. 3 to 6, the drug solution administration apparatus 100 includes: the drug solution container 110 that includes a body 111 being tubular (barrel-shaped) and filled with a drug solution; a housing 120 that holds the drug solution container 110; the pusher 130 that pushes out the drug solution contained in the drug solution container 110; a drive mechanism 140 that moves forward the pusher 130 toward the distal end opening of the drug solution container 110; a detection part 150 that senses a to-be-detected part 134 of the pusher 130 to detect completion of delivery of the drug solution on the basis of a sensing result; and a control unit 160 that controls operations of the drive mechanism to be controlled.

    [0017] As illustrated in Figs. 3 and 4, the housing 120 includes: a housing body 120a that is box-shaped and has an accommodation space 128 formed therein; and a chassis (corresponding to a "support part") 127 that is housed in the accommodation space 128 of the housing body 120a and can be fixed to the housing body 120a.

    [0018] As illustrated in Fig. 3, a window part 123a is formed on a top surface 123 of the housing body 120a so that the inside of the accommodation space 128 can be visually recognized from the outside of the housing 120. The window part 123a is formed by providing a transparent or translucent portion in a part of the housing body 120a.

    [0019] A proximal end opening 125 for inserting the chassis 127 into the accommodation space 128 of the housing body 120a is formed on the proximal end side of the housing body 120a with respect to its longitudinal direction. The proximal end opening 125 of the housing body 120a is covered by a lid member (not illustrated) in a state where the chassis 127 is housed in the accommodation space 128.

    [0020] On a bottom surface 121 of the housing body 120a, a sheet-like sticking part (not illustrated) that can be stuck on the body surface H of the user is provided. In an initial state before the drug solution administration apparatus 100 is attached to the user, a peelable protective sheet is attached to the sticking surface of the sticking part.

    [0021] As illustrated in Fig. 4, the drug solution container 110, the pusher 130, the drive mechanism 140, the detection part 150, the control unit 160, and the power supply unit 170 are held in the chassis 127.

    [0022] The drug solution container 110 is formed of a so-called prefilled type drug solution container. Therefore, the drug solution is filled in advance in an inner cavity 111a of the body 111 of the drug solution container 110. Examples of the drug solution include protein preparations, narcotic analgesics, and diuretics.

    [0023] A sealing member (not illustrated) for preventing leakage of the drug solution is disposed at the distal end opening (discharge port) formed at a distal end 112 of the drug solution container 110. As illustrated in Fig. 3, the distal end opening of the drug solution container 110 is disposed so as to protrude outward from the housing body 120a. On the drug solution container 110, an attachment 115 to be connected to a tube 240, which will be described later (see Fig. 1), is attached to the distal end protruding from the housing body 120a.

    [0024] A body 131 of the pusher 130 is to be inserted into the inner cavity 111a of the body 111 of the drug solution container 110 (see Figs. 4 and 5). A gasket 135 slidable on an inner wall of the drug solution container 110 is disposed at the distal end of the body 131 of the pusher 130. The gasket 135 liquid-tightly seals the proximal end side of the gasket 135 by bringing the outer periphery of the gasket 135 into close contact with the inner peripheral surface of the body 111 of the drug solution container 110 in a liquid-tight manner.

    [0025] In the present embodiment, the gasket 135 is configured to be contractible in a direction (longitudinal direction) in which the pusher 130 moves forward when the pusher 130 moves forward in a state where the gasket 135 is pressed against a distal end inner wall 112a of the drug solution container 110 (see Fig. 5). The gasket 135 can be made of, for example, a rubber material or a flexible resin material such as an elastomer so as to be contractible as described above.

    [0026] As illustrated in Fig. 5, the gasket 135 has a tapered shape in which the outer diameter gradually decreases toward the distal end side. In addition, the gasket 135 is formed to have substantially the same shape as the shape of the distal end inner wall 112a of the drug solution container 110.

    [0027] As illustrated in Fig. 5, the to-be-detected part 134 is provided at the proximal end of the pusher 130. The to-be-detected part 134 is used for detecting completion of delivery of a drug solution by the drug solution administration apparatus 100.

    [0028] The control unit 160 controls drug solution delivery operations of the drug solution administration apparatus 100. The control unit 160 can be formed of, for example, a known microcomputer (electronic circuit element) in which a CPU, a RAM, a ROM, and the like are mounted. The control unit 160 controls operations of the drive mechanism 140, the detection part 150, the power supply unit 170, and a notification unit (not illustrated) in a centralized manner. The control unit 160 further includes a power supply control circuit for minimizing power consumption in the power supply unit 170 during the period of time from manufacture of the drug solution administration apparatus 100 to use thereof by the user. The power supply control circuit will be described later in detail.

    [0029] As illustrated in Fig. 5, the detection part 150 is disposed in the chassis 127. As illustrated in Fig. 6, the detection part 150 detects completion of drug delivery by the drug solution administration apparatus 100 when the to-be-detected part 134 included in the pusher 130 comes into contact with the detection part 150. The detection part 150 can be formed of, for example, a known contact-type sensor that transmits a predetermined electric signal when the sensor comes into contact with the to-be-detected part 134. The control unit 160 obtains information about completion of drug delivery by receiving an electric signal from the detection part 150. Note that the detection part 150 is not particularly limited to any specific configuration as long as the position of the to-be-detected part 134 of the pusher 130 can be detected when the pusher 130 moves forward by a predetermined amount.

    [0030] The power supply unit 170 can be formed of, for example, a known button battery, a power supply stabilizing circuit, and the like. The drug solution administration apparatus 100 is required to be smaller in size. Therefore, a particularly small power source is used as the power source of the power supply unit 170.

    [0031] As illustrated in Fig. 4, the drive mechanism 140 includes a motor 141 that receives a drive current from the power supply unit 170 to generate a rotational driving force, a deceleration mechanism 143 including gears or the like for transmitting the rotational driving force of the motor 141, and a feed screw 147 connected to the deceleration mechanism 143.

    [0032] The feed screw 147 is connected to a proximal end connection part 133 disposed near the proximal end of the pusher 130. The feed screw 147 converts a rotary motion transmitted from the deceleration mechanism 143 into a linear motion to move forward the pusher 130 in the longitudinal direction (X direction). The pusher 130 moves forward toward the distal end side of the drug solution container 110, thereby pushing the drug solution from the inner cavity 111a of the body 111 of the drug solution container 110 to the tube 240 (see Fig. 1).

    (Administration instrument)



    [0033] As illustrated in Figs. 1 and 2, the administration instrument 200 is configured to be connectable to the drug solution administration apparatus 100.

    [0034] The administration instrument 200 includes a connector 210, a needle tube 220 for puncturing the living body, a puncture unit (cannula housing) 230, a tube 240, and a puncture aid 250 for assisting in puncturing the living body with the needle tube 220.

    [0035] The connector 210 is configured to be connectable to the drug solution administration apparatus 100 via an attachment 215 that is fixed to the connector 210. The attachment 215 can be connected to the drug solution administration apparatus 100 by being fitted onto the attachment 115 (see Fig. 4) that is provided near the distal end 112 of the drug solution container 110 protruding outside from the housing 120.

    [0036]  Inside the attachment 215, a needle part for connection (not illustrated) capable of punctuating a sealing member (not illustrated) disposed at the distal end of the drug solution container 110 is disposed. The tube 240 communicates with the inner cavity 111a of the body 111 of the drug solution container 110 via the needle part for connection.

    [0037] Inside the puncture unit 230, a flow path (not illustrated) allowing the tube 240 and the inner cavity of the needle tube 220 to communicate with each other is formed. The drug solution delivered to the puncture unit 230 via the tube 240 passes through the flow path formed inside the puncture unit 230 and the needle tube 220 and is administered into the living body.

    [0038] When the drug solution is going to be delivered to the user, the puncture aid 250 is attached to the puncture unit 230. The puncture aid 250 holds an introducer needle (inner needle) 251. In a state where the puncture aid 250 is attached to the puncture unit 230, the introducer needle 251 protrudes from the tip of the needle tube 220. By puncturing the living body with the needle tube 220 in a state where the introducer needle 251 is inserted through the needle tube 220, the user can insert the needle tube 220 into the living body while preventing breakage or the like of the needle tube 220.

    [0039] After the living body is punctured with the needle tube 220, the puncture aid 250 is removed from the puncture unit 230. When the puncture aid 250 is removed from the puncture unit 230, the introducer needle 251 is removed from the inner cavity of the needle tube 220.

    [0040] After the living body is punctured with the needle tube 220 and the puncture aid 250 is removed, the puncture unit 230 is left on the body surface H of the user with the needle tube 220 indwelling in the living body. In this state, the pusher 130 in the drug solution administration apparatus 100 moves forward inside the drug solution container 110, whereby the drug solution filled in the drug solution container 110 is delivered to the inner cavity of the needle tube 220 via the tube 240 and the flow path in the puncture unit 230.

    [0041] The introducer needle 251 can be formed of, for example, a metal needle. The needle tube 220 can be formed of, for example, a tubular member (cannula) made of resin.

    [0042] As with the drug solution administration apparatus 100, the administration instrument 200 is configured as a patch-type instrument to be attached to the body surface H of the user before use. A contact surface (bottom surface) 231 of the puncture unit 230 of the administration instrument 200 is provided with a sheet-like sticking part (not illustrated) that can be stuck on the body surface H. In an initial state before the administration instrument 200 is attached to the user, a peelable protective sheet is attached to the sticking surface of the sticking part.

    [0043] Schematic configurations of the drug solution administration system 10, the drug solution administration apparatus 100, and the administration instrument 200 have been described above. The drug solution administration apparatus 100 is stored under refrigeration after manufactured in a factory until used by a user. During the storage under refrigeration, main power is not supplied from the power supply unit 170 to the control unit 160. However, in a case where there is a bypass circuit that includes a MOSFET switch 162 and bypasses the power switch 161 as in a conventional power supply control circuit illustrated in Fig. 11, a leakage circuit is formed via the bypass circuit between the microcomputer 164 and the power supply unit 170 separately from the main path. As a result, although the power switch 161 is off, power is continuously consumed during storage under refrigeration. Meanwhile, since the power source of the power supply unit 170 is formed of a button battery, power is continuously supplied from the power supply unit 170 to the control unit 160. The power supply unit 170 is formed of a button battery, and thus it is necessary to minimize the power consumed by the control unit 160 during storage under refrigeration. For this reason, the control unit 160 includes a power supply control circuit as described below.

    [0044] Specific configurations and operations of the power supply control circuit included in the control unit 160 will now be described with reference to Figs. 7 to 11. Fig. 7 is a block diagram of the power supply control circuit included in the control unit. Fig. 8 is an operation flowchart for the drug solution administration apparatus. Fig. 9 is a diagram for explaining operations of the power supply control circuit. Fig. 10 is a block diagram of a power supply control circuit included in a conventional control unit. Fig. 11 is a diagram for explaining operations of a conventional power supply control circuit.

    (Configuration of power supply control circuit)



    [0045] The power supply control circuit included in the control unit 160 includes a power switch (power SW) 161, a MOSFET switch 162 for forming a bypass circuit 166, a MOSFET switch 163 for forming a cut-off circuit 167, and a microcomputer 164 functioning as a control means.

    [0046] The power switch 161 electrically connects the power supply unit 170 that supplies power to the microcomputer 164 and the microcomputer 164. Note that the power switch 161 is a momentary operation type push-button switch that is on only when being pressed.

    [0047] The MOSFET switch 162, which is a first semiconductor switch, is turned on by an ON signal output from the MOSFET switch 163 to bypass the power switch 161. After the power switch 161 is turned on, the MOSFET switch 162 bypasses the power switch 161 to keep the on state of the power switch 161. The MOSFET switch 162 forms a bypass circuit 166 capable of maintaining the connection between the power supply unit 170 and the microcomputer 164, bypassing the power switch 161.

    [0048] The MOSFET switch 163, which is a second semiconductor switch, is turned on by an ON signal output from the microcomputer 164 when the power switch 161 is turned on, and outputs an ON signal to the MOSFET switch 162. The MOSFET switch 163 prevents the microcomputer 164 and the MOSFET switch 162 from being directly electrically connected to each other, and therefore the MOSFET switch 163 cuts off a leakage current flowing between the microcomputer 164 and the power supply unit 170 before power is applied. That is, the MOSFET switch 163 forms the cut-off circuit 167 disposed between the bypass circuit 166 and the microcomputer 164.

    [0049] Therefore, when the MOSFET switch 163 is in the off state, a leakage current generated between the microcomputer 164 and the power supply unit 170 via the bypass circuit 166 is cut off by the cut-off circuit 167, and when the MOSFET switch 163 is turned on by a switch-on signal output from the microcomputer 164, the MOSFET switch 162 is turned on and the bypass circuit 166 bypasses the power switch 161 and maintains the connection between the power supply unit 170 and the microcomputer 164.

    [0050] The MOSFET switch 163 supplies a bypass circuit ON signal for turning on the MOSFET switch 162 to the MOSFET switch 162. Therefore, the MOSFET switch 162 is turned on by the bypass circuit ON signal. The cut-off circuit 167 includes a signal supply source that supplies a bypass circuit ON signal for turning on the MOSFET switch 162.

    [0051] The bypass circuit 166 includes an upstream circuit branched from the upstream side of the power switch 161 and connected to the upstream side of the MOSFET switch 162, a downstream circuit connected from the downstream side of the MOSFET switch 162 to a circuit between the power switch 161 and the power supply unit 170, and a first input circuit for inputting a bypass circuit ON signal to the MOSFET switch 162 connected to the downstream side of the MOSFET switch 163 in the cut-off circuit 167. The first input circuit includes resistors R1 and R2, a capacitor C2, and the like in Fig. 9. The capacitor C2 may be omitted.

    [0052] The cut-off circuit 167 includes a signal supply source connected to the upstream side of the MOSFET switch 163, a second input circuit for inputting a switch-on signal from the microcomputer 164 to the MOSFET switch 163, and a branch circuit branched from the second input circuit and connected to a circuit between the signal supply source and the MOSFET switch 163. The second input circuit includes a resistor R4, a capacitor C1, and the like in Fig. 9. The capacitor C1 may be omitted.

    [0053] The signal supply source is a voltage supply circuit that supplies a voltage for turning on the MOSFET switch 162, and the voltage supply circuit is a circuit branched from a circuit between the downstream side of the power supply unit 170 and the microcomputer 164 for applying a power supply voltage VDD.

    [0054] The microcomputer 164, which is a microcomputer provided with a program for controlling operations of the above-described drive mechanism 140 and the like to be controlled, controls operations of the drive mechanism 140 and the like by executing the program.

    [0055] As examples of the first semiconductor switch and the second semiconductor switch, N-type or P-type MOSFET switches 162 and 163 are illustrated; however, a semiconductor switch other than MOSFET switches such as a transistor or a thyristor may be used as the first semiconductor switch and the second semiconductor switch as long as the semiconductor switch is capable of switching operation.

    (Operations of drug solution administration apparatus)



    [0056] Operations of the drug solution administration apparatus will now be described with reference to the operation flowchart in Fig. 8.

    [0057]  First, the drug solution administration apparatus 100 that has been manufactured in a factory is stored under refrigeration in a factory and in a hospital. Then, when a medical worker is going to use the apparatus, the power switch 161 is turned on (S100). Since the power switch 161 is a momentary operation type push-button switch, the power switch is on only when being pressed. When the power switch 161 is turned on, power is supplied from the power supply unit 170 to the microcomputer 164 as shown in Figs. 7 and 9, and the microcomputer 164 is started (S101). When the microcomputer 164 is started, the microcomputer 164 outputs an ON signal to the MOSFET switch 163 (S102). When the microcomputer 164 outputs the ON signal, the MOSFET switch 163 is turned on (S103). Assuming that the MOSFET switch 163 is, for example, a P-type transistor, the source terminal is fixed to a potential (VDD) equal to or higher than a threshold voltage of the FET, and therefore, an ON signal output from the microcomputer 164 represents that a potential exceeding the threshold is applied from the microcomputer 164 to the gate terminal of the MOSFET switch 163.

    [0058] Next, when the MOSFET switch 163 is turned on, the MOSFET switch 163 outputs an ON signal to the MOSFET switch 162. Assuming that the MOSFET switch 163 is, for example, a P-type transistor, the source potential is fixed to VDD, and therefore, an ON signal output from the MOSFET switch 163 represents that the VDD voltage is applied to the gate terminal of the MOSFET switch 162. Therefore, when the MOSFET switch 163 outputs the ON signal, the MOSFET switch 162 is turned on (S104). When the MOSFET switch 162 is turned on, the bypass circuit 166 bypassing the power switch 161 is formed as illustrated in Fig. 7 (S105). As a result, power is kept supplied from the power supply unit 170 to the microcomputer 164 even after the power switch 161 is turned off.

    [0059] When power is supplied from the power supply unit 170 to the microcomputer 164, the microcomputer 164 reads and executes the drug solution administration program stored in the ROM to cause the pusher 130 (see Figs. 5 and 6) to move little by little so that the drug solution is administered to the subject (S106). When the administration of the drug solution is finished, the microcomputer 164 ends the execution of the drug solution administration program (S107).

    [0060] When the execution of the drug solution administration program is ended, the microcomputer 164 outputs an OFF signal to the MOSFET switch 163 (S108). Assuming that the MOSFET switch 163 is, for example, a P-type transistor, the source terminal is fixed to a potential (VDD) equal to or higher than a threshold voltage of the FET, and therefore, an OFF signal output from the microcomputer 164 represents that a potential lower than the threshold is applied from the microcomputer 164 to the gate terminal of the MOSFET switch 163. Upon receipt of the OFF signal, the MOSFET switch 163 is turned off (S109). Next, the MOSFET switch 162 is turned off as a result of the MOSFET switch 163 being turned off (S110). In this way, the MOSFET switch 163 cuts off a leakage current, which is indicated by an arrow in the figure and which would flow before power is applied from the protection circuit 165 disposed for protecting the microcomputer 164 from noise toward the power supply unit 170 if the MOSFET switch 163 were not provided. Specifically, as illustrated in Fig. 9, the MOSFET switch 163 cuts off a leakage current that would flow from the diode D1 in the protection circuit 165 toward the power supply unit 170 through the resistor R1 and the resistor R2.

    [0061] As illustrated in Figs. 10 and 11, in the case of a conventional power supply control circuit that does not include the MOSFET switch 163, a leakage circuit is formed from the diode Dl, which forms the protection circuit 165 in the microcomputer 164, leading to the power supply unit 170 via the resistors R1 and R2. Although the leakage current is a very small current on the order of µA, the leakage current continuously flows while the drug solution administration apparatus 100 is stored under refrigeration, and thus the power of the power supply unit 170 formed of a button battery having a small electric capacity is wastefully consumed. The power supply control circuit of the present embodiment illustrated in Fig. 9 prevents formation of a leakage circuit by providing the MOSFET switch 163. Note that the leakage current may be reduced by making a resistance value of R1 + R2 extremely high, but practically the resistance value cannot be made extremely high because a very small current noise tends to be more influential when such resistance values are higher. Therefore, it is indispensable to provide the MOSFET switch 163. Therefore, in the case of the power supply control circuit in Fig. 9, the MOSFET switch 163 remains off during the time period when the MOSFET switch 162 is off before the power is turned on, that is, during the time period when the drug solution administration apparatus 100 is stored under refrigeration, thereby preventing formation of a leakage circuit. As a result, no leakage current flows, and thus the power of the power supply unit 170 is not wastefully consumed.

    [0062] Thus, the power supply control circuit and the drug solution administration apparatus 100 including the power supply control circuit according to the present embodiment provides the cut-off circuit 167 to cut off a leakage circuit, thereby achieving power saving during storage. As a result, the electric capacity of the power supply unit 170 can be reduced, thereby achieving reduction in size and cost of the drug solution administration apparatus 100.

    [0063] The power supply control circuit and the drug solution administration apparatus including the power supply control circuit according to the present invention have been described above by means of embodiments. However, the present invention is not limited to the individual configurations described above but can be modified as appropriate on the basis of descriptions in the claims.

    [0064] For example, the power supply control circuit embodiment shown in Fig. 9 does not limit the invention to the illustrated circuit configuration, In addition, the illustrated circuit configuration is an analog circuit configuration, but a digital circuit configuration may also be used.

    Reference Signs List



    [0065] 

    10 Drug solution administration system

    100 Drug solution administration apparatus

    110 Drug solution container

    111 Body of drug solution container

    111a Inner cavity of drug solution container

    112a Distal end inner wall of drug solution container

    120 Housing

    120a Housing body

    127 Chassis

    128 Accommodation space

    130 Pusher

    131 Body of pusher

    134 To-be-detected part

    135 Gasket

    135a Distal end of pusher

    140 Drive mechanism

    150 Detection part

    160 Control unit

    161 Power switch

    162, 163 MOSFET switch

    164 Microcomputer

    165 Protection circuit

    166 Bypass circuit

    167 Cut-off circuit

    170 Power supply unit

    H Body surface




    Claims

    1. A power supply control circuit comprising:

    a control means (164) that controls an operation of a control target;

    a power supply unit (170) that supplies power to the control means (164);

    a power switch (161) that connects the power supply unit (170) and the control means (164);

    a bypass circuit (166) that includes a first semiconductor switch (162) and is capable of bypassing the power switch (161) to maintain connection between the power supply unit (170) and the control means; and

    a cut-off circuit (167) that includes a second semiconductor switch (163) and is disposed between the bypass circuit (166) and the control means (164), wherein the cut-off circuit includes a signal supply source that supplies a bypass circuit ON signal for turning on the first semiconductor switch, wherein

    when the second semiconductor switch (163) is in an off state, a leakage current generated between the control means and the power supply unit (170) via the bypass circuit (166) is cut off by the cut-off circuit (167), and

    when the second semiconductor switch (163) is turned on by a switch-on signal output from the control means (164), the first semiconductor switch (162) is turned on and the bypass circuit (166) bypasses the power switch (161) to maintain connection between the power supply unit (170) and the control means (164);

    wherein the bypass circuit (166) includes: an upstream circuit portion that branches from an upstream side of the power switch (161) and is connected to an upstream side of the first semiconductor switch (162); a downstream circuit portion that is connected from a downstream side of the first semiconductor switch (162) to a circuit portion between the power switch (161) and the power supply unit (170); and a first input circuit (R1, R2, C2) for inputting the bypass circuit (166) ON signal to the first semiconductor switch (162) connected to a downstream side of the second semiconductor switch (163) in the cut-off circuit (167), and

    the cut-off circuit (167) includes: the signal supply source that is connected to an upstream side of the second semiconductor switch (163); a second input circuit (R4, C1) for inputting the switch-on signal from the control means (164) to the second semiconductor switch (163); and a branch circuit portion that is branched from the second input circuit (R4, C1) and is connected to a circuit portion between the signal supply source and the second semiconductor switch (163).


     
    2. The power supply control circuit according to claim 1, wherein the signal supply source is a voltage supply circuit portion that supplies a voltage for turning on the first semiconductor switch (162).
     
    3. The power supply control circuit according to claim 2, wherein the voltage supply circui portion is a circuit portion branched from a circuit portion between a downstream side of the power supply unit (170) and the control means (164).
     
    4. The power supply control circuit according to any one of claims 1 to 3, wherein the control means (164) is a microcomputer that includes a program for controlling an operation of the control target.
     
    5. The power supply control circuit according to any one of claims 1 to 4, wherein the power switch (161) is a momentary operation type push-button switch that is on only when being pressed.
     
    6. The power supply control circuit according to any one of claims 1 to 5, wherein the first semiconductor switch (162) and the second semiconductor switch (163) are N-type or P-type MOSFET switches (162, 163).
     
    7. A drug solution administration apparatus (100) comprising the power supply control circuit according to any one of claims 1 to 6.
     


    Ansprüche

    1. Stromversorgungs-Steuerungsschaltung, umfassend:

    eine Steuerungseinrichtung (164), die einen Betrieb eines Steuerziels steuert;

    eine Stromversorgungseinheit (170), welche die Steuerungseinrichtung (164) mit Strom versorgt;

    einen Leistungsschalter (161), der die Stromversorgungseinheit (170) und die Steuerungseinrichtung (164) verbindet;

    eine Umgehungsschaltung (166), die einen ersten Halbleiterschalter (162) umfasst und in der Lage ist, den Leistungsschalter (161) zu umgehen, um die Verbindung zwischen der Stromversorgungseinheit (170) und der Steuerungseinrichtung aufrecht zu erhalten; und

    eine Unterbrechungsschaltung (167), die einen zweiten Halbleiterschalter (163) umfasst und die zwischen der Umgehungsschaltung (166) und der Steuerungseinrichtung (164) angeordnet ist, wobei die Unterbrechungsschaltung eine Signalversorgungsquelle umfasst, die ein Umgehungsschaltungs-EIN-Signal zum Einschalten des ersten Halbleiterschalters liefert, wobei

    wenn der zweite Halbleiterschalter (163) in einem Aus-Zustand ist, ein Leckstrom, der zwischen der Steuerungseinrichtung und der Stromversorgungseinheit (170) über die Umgehungsschaltung (166) erzeugt wird, durch die Abschaltschaltung (167) abgeschaltet wird, und

    wenn der zweite Halbleiterschalter (163) durch ein von der Steuerungseinrichtung (164) ausgegebenes Einschaltsignal eingeschaltet wird, der erste Halbleiterschalter (162) eingeschaltet wird und die Umgehungsschaltung (166) den Leistungsschalter (161) umgeht, um die Verbindung zwischen der Stromversorgungseinheit (170) und der Steuerungseinrichtung (164) aufrecht zu erhalten;

    wobei die Umgehungsschaltung (166) einen vorgeschalteten Schaltungsabschnitt umfasst, der von einer vorgeschalteten Seite des Leistungsschalters (161) abzweigt und mit einer vorgeschalteten Seite des ersten Halbleiterschalters (162) verbunden ist;

    einen nachgeschalteten Schaltungsabschnitt, der von einer nachgeschalteten Seite des ersten Halbleiterschalters (162) mit einem Schaltungsabschnitt zwischen dem Leistungsschalter (161) und der Stromversorgungseinheit (170) verbunden ist; und eine erste Eingangsschaltung (R1, R2, C2) zum Eingeben des EIN-Signals der Umgehungsschaltung (166) in den ersten Halbleiterschalter (162), der mit einer nachgeschalteten Seite des zweiten Halbleiterschalters (163) in der Abschaltschaltung (167) verbunden ist, und

    die Abschaltschaltung (167) umfasst: die Signalversorgungsquelle, die mit einer vorgeschalteten Seite des zweiten Halbleiterschalters (163) verbunden ist; eine zweite Eingangsschaltung (R4, C1) zum Eingeben des Einschaltsignals von der Steuerungseinrichtung (164) in den zweiten Halbleiterschalter (163); und einen Verzweigungsschaltungsabschnitt, der von der zweiten Eingangsschaltung (R4, C1) abgezweigt ist und mit einem Schaltungsabschnitt zwischen der Signalversorgungsquelle und dem zweiten Halbleiterschalter (163) verbunden ist.


     
    2. Stromversorgungs-Steuerungsschaltung nach Anspruch 1, wobei die Signalversorgungsquelle ein Spannungsversorgungs-Schaltungsabschnitt ist, der eine Spannung zum Einschalten des ersten Halbleiterschalters (162) liefert.
     
    3. Stromversorgungs-Steuerungsschaltung nach Anspruch 2, wobei der Spannungsversorgungs-Schaltungsabschnitt ein Schaltungsabschnitt ist, der von einem Schaltungsabschnitt zwischen einer nachgeschalteten Seite der Stromversorgungseinheit (170) und der Steuerungseinrichtung (164) abgezweigt ist.
     
    4. Stromversorgungs-Steuerungsschaltung nach einem der Ansprüche 1 bis 3, wobei die Steuerungseinrichtung (164) ein Mikrocomputer ist, der ein Programm zur Steuerung eines Betriebs des Steuerziels umfasst.
     
    5. Stromversorgungs-Steuerungsschaltung nach einem der Ansprüche 1 bis 4, wobei der Leistungsschalter (161) ein Drucktastenschalter für kurzzeitigen Betrieb ist, der nur dann eingeschaltet ist, wenn er gedrückt wird.
     
    6. Stromversorgungs-Steuerungsschaltung nach einem der Ansprüche 1 bis 5, wobei der erste Halbleiterschalter (162) und der zweite Halbleiterschalter (163) MOSFET-Schalter (162, 163) vom N-Typ oder P-Typ sind.
     
    7. Vorrichtung (100) zur Verabreichung einer Arzneimittellösung, welche die Stromversorgungs-Steuerungsschaltung nach einem der Ansprüche 1 bis 6 umfasst.
     


    Revendications

    1. Circuit de commande d'alimentation électrique comprenant :

    un moyen de commande (164) qui commande un fonctionnement d'une cible de commande ;

    une unité d'alimentation électrique (170) qui alimente le moyen de commande (164) ;

    un commutateur de puissance (161) qui connecte l'unité d'alimentation électrique (170) et le moyen de commande (164) ;

    un circuit de dérivation (166) qui inclut un premier commutateur à semiconducteur (162) et est apte à dériver le commutateur de puissance (161) pour maintenir une connexion entre l'unité d'alimentation électrique (170) et le moyen de commande ; et

    un circuit de coupure (167) qui inclut un second commutateur à semiconducteur (163) et est disposé entre le circuit de dérivation (166) et le moyen de commande (164), dans lequel le circuit de coupure inclut une source d'alimentation en signal qui fournit un signal ON (marche) de circuit de dérivation destiné à allumer le premier commutateur à semiconducteur, dans lequel lorsque le second commutateur à semiconducteur (163) est dans un état éteint, un courant de fuite généré entre le moyen de commande et l'unité d'alimentation électrique (170) via le circuit de dérivation (166) est coupé par le circuit de coupure (167), et

    lorsque le second commutateur à semiconducteur (163) est allumé par une sortie de signal d'allumage provenant du moyen de commande (164), le premier commutateur à semiconducteur (162) est allumé et le circuit de dérivation (166) dérive le commutateur de puissance (161) pour maintenir une connexion entre l'unité d'alimentation électrique (170) et le moyen de commande (164) ;

    dans lequel le circuit de dérivation (166) inclut : une partie de circuit amont qui se ramifie à partir d'un côté amont du premier commutateur de puissance (161) et est connectée à un côté amont du premier commutateur à semiconducteur (162) ;

    une partie de circuit aval qui est connectée à partir d'un côté aval du premier commutateur à semiconducteur (162) à une partie de circuit entre le commutateur de puissance (161) et l'unité d'alimentation électrique (170) ; et un premier circuit d'entrée (R1, R2, C2) destiné à entrer le signal ON (marche) de circuit de dérivation (166) dans le premier commutateur à semiconducteur (162) connecté à un côté aval du second commutateur à semiconducteur (163) dans le circuit de coupure (167), et

    le circuit de coupure (167) inclut : la source d'alimentation en signal qui est connectée à un côté amont du second commutateur à semiconducteur (163) ; un second circuit d'entrée (R4, C1) destiné à entrer le signal d'allumage à partir du moyen de commande (164) dans le second commutateur à semiconducteur (163) ; et une partie de circuit de ramification qui est ramifiée à partir du second circuit d'entrée (R4, C1) et est connectée à une partie de circuit entre la source d'alimentation en signal et le second commutateur à semiconducteur (163).


     
    2. Circuit de commande d'alimentation électrique selon la revendication 1, dans lequel la source d'alimentation en signal est une partie de circuit d'alimentation en tension qui fournit une tension pour allumer le premier commutateur à semiconducteur (162).
     
    3. Circuit de commande d'alimentation électrique selon la revendication 2, dans lequel la partie de circuit d'alimentation en tension est une partie de circuit ramifiée à partir d'une partie de circuit entre un côté aval de l'unité d'alimentation électrique (170) et le moyen de commande (164).
     
    4. Circuit de commande d'alimentation électrique selon l'une quelconque des revendications 1 à 3, dans lequel le moyen de commande (164) est un micro-ordinateur qui inclut un programme destiné à commander un fonctionnement de la commande cible.
     
    5. Circuit de commande d'alimentation électrique selon l'une quelconque des revendications 1 à 4, dans lequel le commutateur de puissance (161) est un commutateur à bouton-poussoir du type à fonctionnement momentané qui est allumé seulement lorsqu'il est pressé.
     
    6. Circuit de commande d'alimentation électrique selon l'une quelconque des revendications 1 à 5, dans lequel le premier commutateur à semiconducteur (162) et le second commutateur à semiconducteur (163) sont des commutateurs MOSFET de type N ou de type P (162, 163).
     
    7. Appareil d'administration de solution de médicament (100) comprenant le circuit de commande d'alimentation électrique selon l'une quelconque des revendications 1 à 6.
     




    Drawing


























    Cited references

    REFERENCES CITED IN THE DESCRIPTION



    This list of references cited by the applicant is for the reader's convenience only. It does not form part of the European patent document. Even though great care has been taken in compiling the references, errors or omissions cannot be excluded and the EPO disclaims all liability in this regard.

    Patent documents cited in the description