JP2016040184A - Medicine package - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a medicine package which enables a medicine to be smoothly discharged from a container while preventing the medicine stored in the package from contacting with outer air.SOLUTION: A shell, which is provided at a lower edge of a container for storing a fluent medicine and configured to allow an interior part of the container to communicate with an exterior part, is connected with a tube 53 made of an elastic material. The tube 53 has a nozzle 54 for discharging the medicine at its tip. The nozzle 54 includes: a nozzle body 55 having a tapered tip part 58 with a closed tip and in which a discharge hole 55b, which penetrates through a side wall located close to the tip part 58, is formed; and valve rubber 56 which is attached to a tip side outer peripheral surface of the nozzle body 55 excluding the tip part 58 so as to close the discharge hole 55b and is made of an elastic material. When the medicine is pumped from the tube 53, the medicine is overflowed from the discharge hole 55b to be discharged through a gap which is formed by the overflowing medicine and located between the nozzle body 55 and the valve rubber 56.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a drug package, and more particularly to a drug package having a nozzle for discharging a fluid drug.

  As a measuring device for dissolved oxygen concentration, hardness, pH, residual chlorine concentration, etc. for water supply and drainage of various water treatment facilities such as water supply to boilers, cooling towers and other water treatment facilities, prescribed chemicals are applied to sample water collected in the cell. An apparatus for measuring by adding and detecting a change in sample water generated thereby as a change in transmitted light intensity is known (for example, Patent Document 1).

  In this type of measuring device, improvement of the drug addition device has been promoted for the purpose of automatic measurement. For example, Patent Documents 1 and 2 describe an addition device including a drug cartridge and an addition mechanism for gradually adding the drug from the drug cartridge to the sample water in the cell. Here, the medicine cartridge is provided with a medicine packaging body housed in a case, and the medicine packaging body communicates a container for containing a fluid medicine with the inside and the outside of the container. And a tube made of an elastic material having one end connected to the tube and a nozzle for discharging a drug at the other end. On the other hand, the addition mechanism handles the tube by rotating the pressing roller, and thereby discharges the drug that has flowed from the container into the tube through the tube body from the nozzle.

  The container used in the medicine package is a molded product made of a resin material such as polypropylene resin or polyethylene resin, and maintains a certain shape. For this reason, in order to discharge a chemical | medical agent stably from the nozzle of a tube by an addition mechanism, it is necessary to provide the introduction part of external air in a container. However, when outside air flows into the container from the introduction part, the medicine in the container may be denatured due to the influence of the outside air. For example, in the measurement of dissolved oxygen concentration and residual chlorine concentration in sample water, it is necessary to add a redox coloring reagent to the sample water as a drug. Its own redox progresses. Therefore, in the above-described addition apparatus, it is substantially difficult to apply a redox type drug.

Japanese Patent No. 3214400 Japanese Patent No. 3186777

  An object of the present invention is to provide a container for a drug package including a container for containing a fluid drug and a tube made of an elastic material having a nozzle that is connected to the container and discharges the drug at the tip. An object of the present invention is to enable a medicine to be smoothly ejected from a container while avoiding the contained medicine from touching the outside air.

  The drug package of the present invention includes a container for storing a fluid drug, a tube disposed at the lower edge of the container for communicating the inside and the outside of the container, and one end connected to the tube And a first tube made of an elastic material having a nozzle for discharging the medicine at the other end. The container is formed in a bag shape made of a flexible sheet and having gussets on both side edges, and the inside is formed in a funnel shape with the tubular body as a foot portion by welding the inner surfaces of the flexible sheet. The nozzle has a tapered tip with the tip closed and a nozzle body formed with a discharge hole penetrating the side surface near the tip, and the tip of the nozzle body excluding the tip so as to close the discharge hole A second tube made of an elastic material, which is attached to the outer peripheral surface on the side, and overflows the medicine from the discharge hole when the medicine is pumped from the first tube, and the nozzle body formed thereby and the second tube The medicine is discharged through the gap between the two tubes.

  An example of the flexible sheet is a laminated sheet in which a linear low density polyethylene resin film layer, a stretched polyamide resin film layer, an aluminum foil layer and a stretched polyethylene terephthalate resin film layer are laminated from the inner surface side to the outer surface side of the container. is there. Another example of the flexible sheet is a laminated sheet in which a linear low density polyethylene resin film layer, an aluminum oxide-deposited polyamide resin film layer, and a stretched polyethylene terephthalate resin film layer are laminated from the inner surface side to the outer surface side of the container. Is.

  In the drug package using the flexible sheet of these examples, the inside of the container is formed in the above-described funnel shape by welding the inner surfaces of the flexible sheet, for example.

  Since the medicine packaging body of the present invention includes the container, the tube body, and the first tube as described above, the medicine contained in the container can be prevented from coming into contact with the outside air, and from the container through the tube body and the first tube. The medicine can be discharged smoothly.

Schematic of the measuring device using the medicine package concerning one embodiment of the present invention. The longitudinal cross-sectional view which looked at the reagent supply part used in the said measuring apparatus from the II direction of FIG. The perspective view of the said medicine package. Sectional drawing of an example of the sheet | seat used in the said medicine package. Sectional drawing of the other example of the sheet | seat used in the said medicine package. The longitudinal cross-sectional view of the nozzle used in the said medicine package.

  With reference to FIG. 1 and FIG. 2, the measuring apparatus using the chemical | medical agent package which concerns on one Embodiment of this invention is demonstrated. In the figure, a measuring apparatus 1 is for measuring the dissolved oxygen concentration of sample water, and mainly includes a measuring cell 10, a measuring unit 20, and a reagent supplying unit 30.

  The measurement cell 10 is, for example, an opaque container in which a PPS (polyphenylene sulfide) resin is molded into a cylindrical shape. A pair of light transmission windows 10a and 10b facing the side walls are fitted therein, and an opening 11 is formed at the top. Have. An introduction path 12 connected to the flow path 2 for supplying sample water to be measured to the measuring apparatus 1 is provided on the side wall near the bottom of the measuring cell 10. The introduction path 12 includes a filter 13, a constant flow valve 14, and an electromagnetic valve 15 in order from the flow path 2 side, and is set so that sample water from the flow path 2 can be supplied into the measurement cell 10. Further, on the side wall of the measurement cell 10, a drainage channel 16 for discharging the sample water to the outside is provided in the vicinity of the opening 11.

  A stirring device 17 is provided at the bottom of the measurement cell 10. The stirring device 17 includes a stirring bar 17a and a stator 17b. The stirrer 17a is rotatably arranged at the bottom of the measurement cell 10 and incorporates a magnet (not shown). The stator 17b is disposed outside the measurement cell 10 so as to surround the stirrer 17a, and includes an electromagnetic induction coil. The electromagnetic induction coil is set so that a current is supplied from a power source (not shown).

  The measurement unit 20 is for measuring the transmitted light intensity of light of a required wavelength in the sample water, and has a light emitter 21a and a light receiver 21b that are opposed to each other with the light transmission windows 10a and 10b interposed therebetween. . Here, the light emitter 21a is, for example, an LED (light emitting diode) capable of emitting light of a required wavelength, and the light receiver 21b is, for example, from the light emitter 21a that passes through the light transmission windows 10a and 10b. It is a phototransistor capable of receiving light.

  As shown in FIG. 2, the reagent supply unit 30 includes a reagent cartridge 40 that is detachably disposed with respect to the opening 11 of the measurement cell 10, and a discharge for discharging the reagent from the reagent cartridge 40 to the measurement cell 10. The apparatus 60 is mainly provided. The reagent cartridge 40 includes a hollow cartridge case 41 and a medicine package 50 accommodated therein.

  The cartridge case 41 is a resin molded product, and is divided into a front case 42 and a back case 43 in order to accommodate the medicine package 50 therein. A cartridge case 41 formed by combining the front case 42 and the back case 43 includes a container housing portion 44 formed in a substantially rectangular parallelepiped shape and a cylindrical roller entrance / exit portion 45 extending from the center of the bottom surface. Have. A tube stop piece 45 a is formed at the base end of the roller entrance / exit 45 toward the inside of the cartridge case 41. The tube stopper piece 45a is a protrusion for holding a tube body 52 (described later) of the medicine package 50. On the other hand, a nozzle stopper 45 e is formed at the tip of the roller entrance / exit 45 toward the inside of the cartridge case 41. The nozzle stopper piece 45e is a protrusion for holding a nozzle 54 (described later) of the medicine package 50. A slit 45b extending in the vertical direction is formed on the roller case 45 on the back case 43 side. Further, a pressing surface 45c facing the slit 45b is formed in the vertical direction on the inner surface of the roller entrance / exit 45 on the front case 42 side. The pressing surface 45c has a curved surface 45d that is recessed in an arc shape at a substantially central portion in the vertical direction.

  As shown in FIG. 3, the medicine package 50 includes a container 51 for storing a fluid reagent (medicine), a pipe body 52, a tube 53, and a nozzle 54. The container 51 is, for example, a bag-like one formed by airtightly bonding the peripheral portions (shaded portions in FIG. 3) of several flexible sheets 70 cut into a required shape. Each edge has a gusset 71 that expands in the thickness direction by filling the inside with a reagent.

  In this embodiment, the reagent stored in the container 51 is for measuring the dissolved oxygen concentration of the sample water, and a chemical that develops color by reacting with oxygen (for example, indigo carmine) is a reducing agent. In addition, it is dissolved in a solvent such as water or an alcohol compound (in particular, a polyhydric alcohol compound such as a glycol compound).

  The sheet 70 used here has a gas barrier property and a light shielding property capable of preventing the entry of outside air in order to enhance the storage stability of the reagent, and has a chemical resistance and a heat welding property on the inner surface side of the container 51. preferable. As such a sheet 70, for example, as shown in FIG. 4, a linear low density polyethylene resin film layer 701, a stretched polyamide resin film layer 702, an aluminum foil layer 703, and the like from the inner surface side to the outer surface side of the container 51, A four-layer sheet in which each layer of the stretched polyethylene terephthalate resin film layer 704 is laminated with an adhesive layer interposed therebetween can be used. Further, as shown in FIG. 5, the linear low density polyethylene resin film layer 701, the aluminum oxide-deposited polyamide resin film layer 705, and the stretched polyethylene terephthalate resin film layer 704 are bonded from the inner surface side to the outer surface side of the container 51. A three-layer sheet laminated with an agent layer in between can also be used. When these laminated sheets are used, the container 51 can be formed by thermally welding the inner surfaces of several sheets 70 cut into a required shape. In addition, various adhesives, such as a polyurethane type, an epoxy type, a polyester type, a cyanoacrylate type, a polyacrylate ester type, or a polyvinyl acetate type, can be used for the adhesive bond layer of each laminated sheet.

  The tubular body 52 is a resin-made member (for example, a molded product of high-density polyethylene resin) having both ends opened and having chemical resistance, and a connector portion 52a having a reduced diameter is formed on one end side. Further, a receiving portion 52 b that engages with the tube stopper piece 45 a of the cartridge case 41 is formed on the outer periphery of a substantially central portion in the length direction of the tube body 52. The tube body 52 is disposed at the center of the lower edge of the container 51 so as to communicate the inside and the outside of the container 51, and a portion on the connector part 52 a side protrudes from the container 51 from the receiving part 52 b.

  Here, the inner surface of the sheet 70 is hermetically bonded to the outer peripheral surface of the end portion disposed inside the container 51. In addition, an inclined portion 72 is formed in an adhesive portion between the sheets 70 so that the inside of the container 51, that is, the internal space, is formed in a funnel shape with a lower portion of the tubular body 52.

  The tube 53 is made of an elastic material, and is connected to the tube body 52 by inserting the connector portion 52a of the tube body 52 into one end.

  Examples of the elastic material forming the tube 53 include binary fluorine rubbers such as a copolymer of vinylidene fluoride and propylene hexafluoride. Since the binary fluororubber is excellent in gas barrier properties (particularly oxygen barrier properties) and chemical resistance, the reagent contained in the container 51 is an oxidation-reduction type reagent for measuring the dissolved oxygen concentration of sample water. In particular, the tube 53 can be formed by press molding.

  The nozzle 54 is for discharging the reagent contained in the container 51, and is connected to the tip of the tube 53. As shown in FIG. 6, the nozzle 54 includes a tubular nozzle body 55 having a base end opened and a tapered distal end portion 58 closed, and an outer peripheral surface on the distal end side excluding the distal end portion 58 of the nozzle body 55. Insect rubber 56 attached to the. The nozzle body 55 is a resin-made member (for example, a molded product of high-density polyethylene resin) having chemical resistance, and its inner diameter is set uniformly in the length direction. A connector portion 55 a is formed on the proximal end side of the nozzle body 55, and this connector portion 55 a is inserted into the distal end of the tube 53. On the other hand, a discharge hole 55 b penetrating in a direction orthogonal to the central axis of the nozzle main body 55 is formed on the side surface in the vicinity of the front end portion 58 on the front end side of the nozzle main body 55. That is, the nozzle body 55 has two discharge holes 55b communicating with the inside thereof. A thick stepped portion 55 c is formed on the outer periphery of the substantially central portion in the length direction of the nozzle body 55. A receiving portion 55d that engages with the nozzle stopper piece 45e of the cartridge case 41 is formed on the outer periphery on the base end side of the stepped portion 55c. Further, a groove 55e is formed on the outer periphery on the tip side of the stepped portion 55c, and a seal ring 57 (for example, a D ring made of fluoro rubber) is attached to the groove 55e. The insect rubber 56 is a tube made of an elastic material having chemical resistance (for example, polyolefin rubber), and is attached to the outer peripheral surface on the tip side of the nozzle body 55 so as to close the two discharge holes 55b.

  Such a medicine package 50 is arranged in a state where the container 51 stands up in the container storage portion 44 with the receiving portion 52 b of the tube body 52 engaged with the tube stopper piece 45 a of the cartridge case 41. The tube 53 extends downward in the roller entrance / exit 45, and the receiving portion 55d of the nozzle body 55 is engaged with the nozzle stop piece 45e of the cartridge case 41. As a result, the fluid reagent contained in the container 51 is filled into the tube 53 through the tube body 52, and the outflow from the discharge hole 55 b of the nozzle body 55 is blocked by the insect rubber 56. When the reagent cartridge 40 is mounted, the tip portion of the nozzle 54 is disposed so as to protrude into the measurement cell 10 and is airtightly mounted on the inner peripheral surface of the measurement cell 10 by the seal ring 57.

  The discharge device 60 is for discharging the reagent stored in the container 51 of the medicine package 50, and mainly includes a rotation drive shaft 61, a drive arm 62, and a pressing roller 63 connected to a motor (not shown). ing. The rotation drive shaft 61 is disposed outside the slit 45b and can rotate counterclockwise in FIG. One end of the drive arm 62 is connected to the rotational drive shaft 61, and a pressing roller 63 is rotatably attached to the other end. The drive arm 62 can be rotated in the counterclockwise direction as indicated by a two-dot chain line in FIG. It is set to be accessible.

  The above-described measuring apparatus 1 includes a control device (not shown), and the control device controls the operation of each unit to measure the dissolved oxygen concentration of the sample water as follows.

Next, the water quality inspection operation of the sample water by the above-described measuring apparatus 1 will be described.
First, the electromagnetic valve 15 of the measuring device 1 is set to an open state. As a result, the sample water flows from the flow path 2 into the measurement cell 10 through the introduction path 12. At this time, impurities contained in the sample water are removed by the filter 13. Further, the flow rate of the sample water flowing into the measurement cell 10 is controlled by the constant flow valve 14. The sample water continuously flowing into the measurement cell 10 fills the measurement cell 10 and is continuously discharged from the drainage channel 16 to the outside. At this time, when the electromagnetic induction coil of the stator 17b is energized, the magnet in the stirrer 17a receives the magnetic field generated thereby, whereby the stirrer 17a in the measurement cell 10 rotates. As a result, the sample water flowing into the measurement cell 10 is agitated, and the measurement cell 10 is pre-washed with the sample water.

  After the pre-cleaning as described above, when the energization of the electromagnetic induction coil of the stator 17b is temporarily stopped and the electromagnetic valve 15 is closed, the flow of the sample water into the measurement cell 10 is cut off, and the measurement cell 10 The sample water is stored up to the level of the drainage channel 16. As a result, the tip of the nozzle 58 is disposed in the stored sample water. In this state, the measurement unit 20 is operated to irradiate light from the light emitter 21a toward the light receiver 21b. And the transmitted light intensity | strength of sample water is measured about the light irradiated from the light-emitting body 21a.

  Next, energization of the electromagnetic induction coil of the stator 17b is started to restart the rotation of the stirrer 17a. At the same time, the motor of the discharge device 60 is driven to rotate the rotation drive shaft 61 while continuing the state. As a result, the drive arm 62 rotates counterclockwise in FIG. 2, and the pressing roller 63 handles the tube 53 downward while pressing the tube 53 against the pressing surface 45c. The reagent that has flowed out of the container 51 into the tube 53 through the tube body 52 is pumped to the nozzle 54 and overflows from the discharge hole 55 b of the nozzle body 55. Thereby, a gap is formed between the nozzle body 55 and the insect rubber 56, and a certain amount of reagent is discharged into the sample water in the measurement cell 10 through this gap. For this reason, when the rotation operation of the drive arm 62 is repeated, the predetermined amount of the reagent is intermittently and gradually injected into the sample water every time the drive arm 62 rotates.

  Here, since the container 51 is made of the flexible sheet 70 and has the towns 71 on both side edges, the town 71 contracts in the closing direction as the reagent is discharged from the nozzle 54. For this reason, the container 51 can discharge a reagent from the nozzle 54, without flowing in external air, and can maintain stably the stored reagent, without denature | denaturating by the influence of external air. Further, since the inner space of the container 51 is formed in the funnel shape as described above, the contained reagent can be smoothly concentrated on the tube portion 52, thereby allowing the reagent to flow smoothly into the tube portion 52. Can be dropped. For this reason, the reagent accommodated in the container 51 can be used up without remaining.

  The reagent injected into the measurement cell 10 as described above is dissolved in the sample water stirred by the rotation of the stirring bar 17a and reacts with dissolved oxygen contained in the sample water to change the color of the sample water.

In the reagent injection process as described above, the control device continues to rotate the stirrer 17a, and continuously measures the transmitted light intensity (I) of the sample water that changes color due to the gradually injected reagent by the measuring unit 20. Measure automatically. At this time, the control device determines the amount of change in the change in transmitted light intensity associated with an increase in the amount of reagent injected into the sample water. The amount of change in transmitted light intensity determined here is usually the difference (ΔI) in transmitted light intensity before and after the fixed amount of reagent described above is injected. Usually, the transmitted light intensity of the sample water gradually decreases according to the number of reagent injections (that is, the number of rotations of the drive arm 62). Here, when all of the dissolved oxygen in the sample water reacts with the reagent injected before the Xth time, the discoloration of the sample water proceeds even if more reagents are injected in the injection operation after the Xth time. The transmitted light intensity of the sample water is difficult to change. That is, the difference (I ¹ −I ² , that is, ΔI) between the transmitted light intensity I ¹ after the Xth injection of the reagent and the transmitted light intensity I ² after the X + 1th injection is a slight difference. . Therefore, when ΔI becomes less than the specified amount, even if more reagents are injected into the sample water, the reagents are not involved in the reaction with dissolved oxygen in the sample water and remain in the sample water as they are. Will do.

Therefore, when it is determined that ΔI has become equal to or less than the predetermined amount, the control device stops the rotation operation of the drive arm 62. Thereby, the additional injection of the reagent into the sample water is stopped. Subsequently, the control device obtains a ratio (transmitted light intensity ratio: I ^B / I ^A ) between the transmitted light intensity (I ^B ) of the sample water and the transmitted light intensity (I ^A ) before the reagent injection at that time. Then, based on the calibration curve data of the transmitted light intensity ratio and the dissolved oxygen concentration prepared in advance, the control device calculates the dissolved oxygen concentration in the sample water.

  After measuring the dissolved oxygen concentration in the sample water in this way, when the stirrer 17a is rotated again and the electromagnetic valve 15 is opened, the sample water containing the reagent stored in the measurement cell 10 is introduced from the introduction path 12. The sample water is washed away by the newly flowing sample water, and is discharged from the drainage channel 16 to the outside. Thereby, the cleaning of the measurement cell 10 is completed.

  In the water quality test of the sample water as described above, when the reagent filled in the medicine package 50 runs out, the reagent cartridge 40 is removed and the front case 42 and the rear case 43 of the cartridge case 41 are divided. Although it is possible to replace only the medicine package 50, it is usually preferable to replace the entire removed reagent cartridge 40 with another reagent cartridge 40.

  In the above-described embodiment, a case has been described in which a reagent for that purpose is stored in the container 51 of the drug package 50 in order to measure the dissolved oxygen concentration of the sample water. However, this reagent (drug) measures the sample water. Other water quality indicators such as residual chlorine concentration, hardness, silica concentration, M alkalinity or pH can be changed. Here, as for the residual chlorine concentration, it is necessary to use an oxidation-reduction type reagent (drug) that is easily denatured by the influence of outside air as in the case of measuring the dissolved oxygen concentration. A reagent that is not easily affected by outside air, such as a complexing agent, can be used. For this reason, in the medicine package 50 for measuring other water quality indicators, a polyolefin rubber such as the trademark “Farmed” of Saint-Gobain Co., Ltd. can be used as an elastic material forming the tube 53. Can be formed by extrusion.

50 Drug Packaging 51 Container 52 Tube 53 Tube 54 Nozzle 55 Nozzle Body 55b Discharge Hole 56 Bug Rubber 58 Tip 70 Sheet 71 Town

Claims (1)

A container for containing a fluid drug;
A tube disposed on the lower edge of the container for communicating the inside and the outside of the container;
A first tube made of an elastic material having one end connected to the tube and a nozzle for discharging the medicine to the other end;
The container is formed of a flexible sheet and formed into a bag shape having a gusset on both side edges, and the inside of the flexible sheet is formed in a funnel shape with the tubular body as a foot portion by welding between the inner surfaces of the flexible sheet,
The nozzle has a tapered tip portion with a closed tip, a nozzle body in which a discharge hole penetrating a side surface in the vicinity of the tip portion is formed, and the tip portion is excluded so as to close the discharge hole A second tube made of an elastic material attached to the outer peripheral surface of the nozzle body on the tip side, and overflowing the medicine from the discharge hole when the medicine is pumped from the first tube, Discharging the drug through the gap between the nozzle body and the second tube formed thereby,
Drug package.

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