AUTOMATIC APPLICATOR FOR LIQUID PHARMACEUTICAL PREPARATIONS, PARTICULARLY FOR INSULIN

Abstract

An injection device includes a housing with an inspection window and at least two springs. One of the at least two springs is a driving helical spring. A spring block is connected to the housing and secured against rotation relative to the housing. A coupling tube extends above the spring block and above the housing. The injection device includes a plunger at least partially surrounded by the coupling tube. The driving helical spring is connected to the spring block. The coupling tube is at least partially surrounded by the driving helical spring. At least a portion of the proximal end of the plunger is narrower than a first internal diameter of the coupling tube and wider than a second internal diameter of the coupling tube. The rotatable dose knob, the spring block, the coupling tube, the plunger, and the driving helical spring are arranged coaxially.

Claims

1. An injection device comprising: a housing comprising an inspection window, at least two springs, one of the at least two springs being a driving helical spring, a spring block connected to the housing and secured against rotation relative to the housing, a coupling tube extending above the spring block and above the housing a plunger at least partially surrounded by the coupling tube, wherein the driving helical spring is connected to the spring block, wherein the coupling tube is at least partially surrounded by the driving helical spring, wherein the coupling tube comprises a first internal diameter and a second internal diameter, wherein the plunger comprises a proximal end and a distal end, wherein at least a portion of the proximal end of the plunger is narrower than the first internal diameter of the coupling tube and wider than the second internal diameter of the coupling tube, wherein the coupling tube comprises at least a first protrusion and a second protrusion, wherein at least a portion of the first protrusion of the coupling tube is above the driving helical spring and above the spring block, wherein at least a portion of the second protrusion of the coupling tube is below the inspection window of the housing, wherein the spring block comprises an outer wall, an internal wall and a protrusion, wherein at least a portion of the protrusion of the spring block is curved, wherein the curved portion of the protrusion of the spring block at least partially extends beyond an outer diameter of the outer wall of the spring block, wherein the spring block comprises a first hole and a second hole, wherein the first hole of the spring block is separated from the second hole of the spring block by the internal wall of the spring block, wherein the coupling tube extends through the first hole of the spring block and is arranged non-coaxially with the second hole of the spring block, wherein the coupling tube is at least partially surrounded by a substantially cylindrical wall of a rotatable dose knob, wherein the substantially cylindrical wall of the rotatable dose knob at least partially covers the housing, the curved protrusion of the spring block, the outer wall of the spring block, the driving helical spring, and the internal wall of the spring block, and wherein the rotatable dose knob, the spring block, the coupling tube extending through the first hole, the plunger, and the driving helical spring are arranged coaxially.

2. The injection device according to claim 1, wherein the curved protrusion of the spring block at least partially covers a curved portion of a wall of the housing.

3. The injection device according to claim 1, wherein a distal end of the housing comprises an external diameter and a proximal end of the housing comprises an external diameter, the external diameter of the proximal end of the housing being smaller than the external diameter of the distal end of the housing.

4. The injection device according to claim 1, wherein the coupling tube comprises an outer diameter that is smaller than the internal diameter of the first hole of the spring block and is larger than the internal diameter of the second hole of the spring block.

5. The injection device according to claim 1, wherein the plunger comprises a thread and at least one longitudinal groove.

6. The injection device according to claim 1, wherein the plunger comprises at least two longitudinal grooves.

7. The injection device according to claim 1, wherein the spring block comprises a flange.

8. The injection device according to claim 1, wherein the at least two springs comprise a second spring which is a helical spring.

9. The injection device according claim 1, wherein the rotatable dose knob is coupled to the coupling tube such that when a dose is to be increased, the coupling tube rotates clockwise relative to the housing.

10. The injection device according claim 1, wherein when the coupling tube is rotated by turning the rotatable dose knob for increasing a dose, a resilient arm of a pawl is displaced radially.

11. The injection device according claim 5, wherein the longitudinal groove of the plunger is adapted to receive a key.

12. The injection device according to claim 11, wherein the key is rotationally blocked in relation to the plunger.

13. The injection device according to claim 12, wherein the key is a portion of a plunger guide, the plunger guide being located within an interior of the housing.

14. The injection device according claim 13, wherein the plunger guide is axially movable relative to the housing.

15. The injection device according claim 1, wherein the driving helical spring is a twisted spring.

16. The injection device according claim 1, wherein a clutch element of the coupling tube is coupled with a resilient arm of a pawl.

17. The injection device according claim 1, wherein when the coupling tube is rotated in a clockwise direction, a resilient arm of a pawl is displaced on slide edges, from one blocking edge to a neighboring edge.

18. The injection device according to claim 1, wherein the at least two springs comprise a second spring, and the second spring is at least partially outside the housing.

19. The injection device according to claim 1, wherein the at least two springs comprise a second spring that comprises at least one coil.

20. The injection device according to claim 1, wherein the plunger comprises a proximal non-threaded end and a distal threaded end.

21. The injection device according to claim 20, wherein at least a portion of the proximal non-threaded end of the plunger is wider than the distal threaded end of the plunger.

22. The injection device according to claim 1, wherein the first hole of the spring block comprises an internal diameter larger than an internal diameter of the second hole of the spring block.

23. The injection device according to claim 1, wherein the rotatable dose knob is substantially axially immovable.

Description

DRAWINGS

[0018] In order that the disclosure may be well understood, there will now be described various forms thereof, given by way of example, reference being made to the accompanying drawings, in which:

[0019] FIG. 1 presents the longitudinal section of the automatic applicator, without an exchangeable container and its casing;

[0020] FIG. 2 presents the cross-section B-B of the ratchet mechanism of the automatic applicator with the pawls meshed with the toothed ring of the nut;

[0021] FIG. 3 presents the cross-section C-C of the automatic applicator from the FIG. 1, in the place, in which the trigger mechanism meshes with the toothed ring of the nut;

[0022] FIG. 4 presents the cross-section 0-0 of the automatic applicator from the FIG. 1, showing the system blocking the rotation of the scale, which defines the working range of the automatic applicator;

[0023] FIG. 5 presents pictorially the cross-section E-E of the automatic applicator from the FIG. 1, showing the positioning of the elements of the arrangement blocking the plunger against rotation;

[0024] FIG. 6 presents the front axonometric view of the automatic applicator from the FIG. 1, with parts of the housings removed, showing the advantageous mutual positioning of the elements of the internal mechanisms of the automatic applicator; and

[0025] FIG. 7 presents the exploded front axonometric view of the automatic applicator from the FIG. 1.

DETAILED DESCRIPTION

[0026] The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses.

[0027] As shown in the FIGS. 1, 6 and 7, an automatic applicator for liquid pharmaceutical preparations, particularly for insulin, more particularly for multiple injection application of set doses of a medicine from an exchangeable container, comprises the body housing 1, connected to the housing 2 of the exchangeable container with a medicine (not shown in the drawings). The insulin is expelled by the plunger 12, linearly displaced by means of the driving unit, suitable for immobilizing, driving, leading linearly and blocking rotation of the plunger 12, driven via a double clutch unit by the tensioning spring 15, wherein the driving tensioning spring 15 is a twisted spring situated in the body housing 1, tensioned by the rotary hand-dose-setting ring 3 also via a double clutch unit, wherein the driving unit is activated by the trigger unit and the displaceable indicating cylinder 14 is situated on the tensioning spring holder 13 and a scale 5.7 with the scale visible in the inspection window 1.1 deposited on the ratchet barrel 5.

[0028] The automatic applicator for liquid pharmaceutical preparations, particularly for insulin, more particularly for multiple injection application of set doses of a medicine from an exchangeable container, operates as follows.

[0029] In order to replace the insulin container you should unscrew the container housing 2, which is connected to the body housing 1 (FIG. 1) by turning it anticlockwise. After unscrewing the container housing 2, the plunger block guide 11 and the seat element 9 become automatically disengaged owing to the action of the disengaging spring 10 by means of moving the plunger block guide 11 coaxially in the direction of plunger 12. This enables hand backing of the plunger 12 by using the force in the axial direction to push it into the housing 1. The plunger ending 12.1 is independently rotated on the plunger 12. The coupling between the plunger 12 and the nut 7 is by a quick thread, so while being pushed into the housing 1 the plunger 12 screws itself into the nut 7. The plunger should be pushed until it almost completely hides in the housing 1, which allows a new container with insulin to be inserted.

[0030] The nut 7 is coupled to the plunger 12 by a thread having pitch enabling application of the appropriate dose of insulin. Further, the nut 7 is bearingly mounted in the seat element 9, advantageously by means of a ball bearing 8.

[0031] Then you should remove the needle (not shown) mounted on the container housing 2 by turning it anti-clockwise, remove the empty container by withdrawing it from the housing 2 and install a new container.

[0032] To install a new container you should insert it into the container housing 2, which you should place in the body housing 1 by turning it clockwise. Next you should fix a new needle and cover it with the protecting cap.

[0033] The dose-setting is carried out by turning the rotary hand-dose-setting ring 3 (FIG. 1) clockwise. The currently set dose can be seen on the cylindrical part of the ratchet barrel 5 by means of the inspection window 1.1 situated in the housing 1, which together with the scale 5.7 deposited linearly on a under the block keys 5.6 comprises the indicating arrangement. The cylinder of the ratchet barrel 5 is scaled by every four units and the turning of the rotary hand-dose setting ring 3 is accompanied by a characteristic clicking at every two units, corresponding to 0.02 ml of insulin. The dose-setting can be realized up to two units, wherein the scale 5.7 visible through the inspection window 1.1, stops at any value or between the given dose values, which is easy to check as two consecutive doses are then seen in inspection window 1.1, and a red line indicator shows the position between them.

[0034] The rotary hand-dose-setting ring 3 is rigidly connected to the coupling sleeve 6. When a dose is to be increased, the coupling sleeve 6 (FIG. 2) is rotated clockwise (looking in the direction of the needle) wherein the resilient arm of the pawl 5.3 is displaced on the slide edges 7.5 of the ratchet tooth ring 7.1 of the stationary driving nut 7, from one blocking edge of the ratchet tooth ring 7.1 to the neighbour edge(s) depending on the angle of rotation. The ratchet barrel 5 is driven by the coupling sleeve 6 by means of the steering recess 6.1 made in the inner wall of the coupling sleeve 6 meshed with the key 5.4 situated in the inner wall of the ratchet barrel 5. Therefore, when the coupling sleeve 6 is rotated, the ratchet barrel 5 is rotated together with it. During the rotation in the clockwise direction, the resilient arm of the pawl 5.3 is displaced radially, alternatively inside and outside.

[0035] The ratchet barrel 5 is rigidly connected to the spring 15, which in turn is connected to spring block 4. The spring block 4 is rigidly connected to the housing 1 and secured against rotation.

[0036] During the dose setting the nut 7 is immobilized by the trigger unit 13 by means of the rectangular grooves 7.7 (FIG. 3) situated on the circumference of the nut 7, collaborating with the key 13.1 of the trigger unit 13.

[0037] The operational range of the automatic applicator is defined by two block keys 5.6 (FIG. 4) placed directly on the circumferential surface of the ratchet barrel 5, collaborating with two keys 1.3 on the internal part of the cylindrical surface of the cylindrical housing 1 placed above the inspection window 1.1. The keys are situated on the opposite sides and simultaneously slightly displaced axially. Such arrangement enables realizing one incomplete rotation of the dose setting elements.

[0038] After setting the dose you can actuate the dosing of insulin by pressing the trigger unit 13 in the direction of the needle. The trigger unit 13 should be pressed throughout the whole time of the insulin application. The range of the trigger displacement is defined by the displacement of the key 13.1 in the corresponding groove 1.2 in the body housing 1. After pressing the trigger unit 13 the nut 7 is released by the disengagement of the ring with the rectangular grooves 7.7 and the key 13.1 of the trigger unit 13. The mechanism starts rotating, driven by the force from the tensioning spring 15. The nut 7 causes the unscrewing of the plunger 12 on the thread 12.1 of the plunger 12, The rotation of the plunger is blocked by the key 11.1 of the plunger block guide 11 and the recess 12.2 made in the plunger 12 (FIG. 5). The plunger 12 acts directly on the piston of the insulin container, placed in the container housing 2. It causes the injection of insulin from the needle mounted on the container housing 2. This action is accompanied by the reverse movement of the whole mechanism to its initial position, i.e. the tensioning spring 15 unwinds, and the ratchet barrel 5 with the scale 5.7 returns to the position O.

[0039] After completing the dose-setting you can release the trigger unit 13. The trigger unit 13 will then automatically return to its initial position urged by the spring 14, which is placed directly under the trigger unit 13, and will again block the nut 7.

[0040] The double action clutch, best seen in the FIG. 2, which presents the cross-section B-B of the ratchet mechanism of the automatic applicator with the pawls meshed with the toothed ring of the nut, comprises the coupling sleeve 6 radially coupled with the body of the ratchet barrel 5 and coupled with the pawls 5,3 having hooks separately meshed with the gear ring 7.5 of the driving nut 7.

[0041] The coupling sleeve 6 is rigidly connected to the rotary hand-dose-setting ring 3 and the body of the ratchet barrel 5 is rigidly connected to the tensioning spring 15 holder, in the form of a protective sleeve, which enables transfer of the rotation of the rotary hand-dose-setting ring 3 to the tensioning spring 15 holder.

[0042] The tensioning spring 15 (FIG. 1 and FIG. 6) is mounted, form the side of the needle, in the tensioning spring 15 holder, in the form of a protective sleeve rigidly connected to the body of the ratchet barrel 5.

[0043] The integrated driving unit (FIG. 5), suitable for immobilizing, driving, leading linearly and blocking rotation of the plunger 12 comprises a plunger block guide 11 and a driving nut 7. The construction of the integrated driving unit enables hand backing of the plunger 12 by pushing it into the driving nut 7 in such way that it minimally protrudes from the housing, allows a new container, ego with insulin, to be inserted.

[0044] The nut 7 (as mentioned above) is coupled to the plunger 12 by a thread having pitch enabling application of the appropriate dose of insulin. Additionally, the plunger 12 comprises at least one longitudinal groove enabling linear displacement of the plunger 12 in the plunger block guide 11 by means of at least one key.

[0045] The trigger unit (FIG. 3) constitutes the trigger 13 with the key 13.1 slidingly displaced in the groove 1.2 situated in the housing 1 in order to block the ring with the rectangular grooves 7.7 of the driving nut 7.

[0046] It should be noted that the disclosure is not limited to the embodiment described and illustrated as examples. A large variety of modifications have been described and more are part of the knowledge of the person skilled in the art. These and further modifications as well as any replacement by technical equivalents may be added to the description and figures, without leaving the scope of the protection of the disclosure and of the present patent.