BE1017356A6 - Dispenser for viscous material, e.g. tooth filler paste, includes battery powered vibration motor for reducing material viscosity - Google Patents

Abstract

The dispenser has a pistol-shaped casing (20) with a grip part (21) and barrel part (22), the outlet end of the barrel being provided with a nozzle (25) adjacent to a space (24) for receiving a cartridge containing the viscous material. A plunger (30) inside the barrel is used to press the material out of the cartridge and out through the nozzle. The plunger is displaced by an actuator (40) inside the barrel. An operating mechanism (50) is provided for the plunger. A vibration motor (60) is connected to the plunger or actuator and can be powered by a battery (70) housed inside the grip part. A switch (71) is used to turn the motor on and off.

Description

Title: Dispenser for pasty mass

The present invention generally relates to a dispenser for pasty or viscous mass. By way of example, the dispenser is intended for dispensing a filling material for filling a tooth by a dentist, and the present invention will be specifically explained for this application example, but the invention is not limited thereto; in another example the dispenser is intended for dispensing an adhesive.

When a dentist starts filling a tooth, he applies a portion of a dental filler to the tooth cavity with a dispenser. Typically this is a composite material that hardens after application, for example under the influence of UV light, ambient air, moisture, etc. Since the filling of molars in this way, and suitable materials for this, are known per se, a further description thereof may be omitted be left.

An important problem here is that the filler applied must completely fill the tooth cavity. Imperfections in this regard can lead to cavities in which, for example, bacterial growth can occur, which can further affect the molar in question. A complicating factor then is that a proper filling of the tooth cavity can actually only be achieved if the filler has a low viscosity during application; however, if the composition of the filler is selected such that the filler, typically a plastic composite containing a resin, has a low viscosity, a relatively strong shrinkage is typically to be expected during curing. Conversely, if the composition of the filler is selected such that the filler hardly shrinks when hardened, this is typically accompanied by a high viscosity, and filling the tooth cavity is difficult.

It is known to apply the filler with the aid of a gun-shaped dispenser, which at its outlet is provided with a narrow tubular, usually tapered nozzle through which the filler is pressed. If the viscosity of the filler is high, it is particularly difficult to press the filler through the nozzle, and this takes a lot of force.

To alleviate these problems, it has already been proposed to exert a vibration on the filler in the dispenser which results in the viscosity of the filler being lowered. As long as the filler "senses" the vibrations, i.e. within the dispenser and in the immediate vicinity of the nozzle, the filler has a low viscosity, and thus it is relatively easy to press the filler out of the nozzle and the tooth cavity with relatively little force. good to fill. When the dispenser is removed, the filler in the tooth cavity immediately returns to a large viscosity. This has the additional advantage that the filler will not easily drain out of the tooth.

With dispensers described in the prior art, the vibrations have frequencies in the ultrasonic region.

Generating these vibrations often requires complicated external equipment, which must transfer the vibrations to the dispenser via hoses or the like. This makes the total installation bulky and expensive, and makes the dispenser difficult to handle. In this connection it is significant that dispenser with vibrations are not available on the market. Dispensers have also been described using a piezo element to generate the vibrations, but it is difficult to obtain vibrations of sufficient energy. Furthermore, the vibration generating element is typically described as being positioned at a relatively large distance from the nozzle, so that the vibrations have to travel a fairly long way in the dispenser and it is difficult to get sufficient vibration energy in the right place.

The present invention has for its object to eliminate the said problems or at least to reduce them. More particularly, it is an object of the present invention to provide a simple and relatively inexpensive instrument that is easy to handle and capable of exerting an effective viscosity-lowering vibration on the filler to obtain a good fill result.

According to an important aspect of the present invention, the dispenser is provided with a simple battery-powered vibrator motor. Experiments have shown that good results can be achieved in this way. The motor can be a relatively small motor with an eccentric weight on its output shaft. Such motors are known per se, for example for toothbrushes, so that the construction of the motor need not be further explained. The motors mentioned are manufactured in large numbers and are therefore relatively inexpensive.

These and other aspects, features and advantages of the present invention will be further elucidated by the following description with reference to the drawings, in which like reference numerals indicate like or similar parts, and in which: figure 1 schematically shows a longitudinal section of a possible embodiment of a dispenser proposed by the present invention; Figure 2 schematically shows a detail of another embodiment of a dispenser proposed by the present invention.

In Figure 1, a dispenser 1 according to the present invention is schematically shown to illustrate its operating principle. The dispenser 1 comprises a generally gun-shaped housing 20, with a grip portion 21 and a running portion 22, the grip portion 21 being substantially perpendicular to the running portion 22. At the free end 23 of the running portion facing away from the grip portion 21, also indicated as a front end, the running portion 22 has a receiving space 24 for receiving an ampoule or cartridge 2 with a filling paste. Furthermore, a dispensing nozzle 25 is shown at the front end, which is usually a fixed part of the cartridge, but that is not essential: it is also possible that the dispensing nozzle is a separate component to be coupled to the cartridge or an exchangeable or non-exchangeable component of the cartridge. house is 20. Since dispensers with receiving spaces for such cartridges are known per se, for example from EP 1,210,025 or EP 0,726,738, a further explanation of this construction is not necessary.

Near the receiving space 24, a piston 31 is axially slidably received in the running portion 22. In this embodiment, the plunger 30 has a substantially T-shaped longitudinal section, with an axial stem 32 and an anvil 31 with a diameter larger than that of the stem 32 attached to the end of the stem facing away from the receiving space 24. in this case, a helical spring return 33, which is positioned against the front end 23 of the housing 20, engages under the anvil 31 to push the stem 32 away from the receiving space 24.

An actuator 40 is also axially slidably received in the running portion 22. A front end 41 of the actuator 40 abuts the anvil 31 of the plunger 30. It is also possible that the plunger 30 is fixedly attached to the actuator 40 or that the plunger 30 and the actuator 40 are formed as an integrated whole.

The dispenser 1 is furthermore provided with an operating mechanism 50 for operating the actuator 40. The operating mechanism 50 has the task of exerting a user-adjustable force on the actuator 40, so that it together with the plunger 30 in the direction is pressed from the receiving space 24 against the return force of the return spring 33, wherein the stem 32 will penetrate into the cartridge 2 and the pasty mass present therein will be pressed out via the nozzle 25, as will be clear to a person skilled in the art.

The return spring 33 has the task of pushing back the plunger 30 when the force exerted by the user is reduced.

The operating mechanism 50 can be implemented in various ways, as will be clear to a person skilled in the art. In the illustrated embodiment, the operating mechanism 50 comprises a lever 51 with two lever arms 52 and 53, which lever 51 is pivotally coupled to the housing 20 at a pivot point 54. A first lever arm 52 extends substantially parallel to the handle 21 on the front of that handle.

A second lever arm 53 is engaged with the actuator 40. This engagement may, for example, be implemented by a pin displaceable in a slot, as shown. When a user grasps the handle 21 and the first lever arm 52 with his hand and then squeezes, the first lever arm 52 is pivoted towards the handle 21 by the pinch force, counterclockwise in the drawing. The second lever arm 53 then pivots in the same direction, thereby pushing the actuator 40 forwards, i.e. in the direction of the nozzle 25, in which case the pin 55 at the end of the second lever arm 53 forces an adaptive displacement the slot 45 of the actuator 40 undergoes.

According to an important aspect of the present invention, a vibration motor 60 is mounted in or on the slidable actuator 40. In the figure, the actuator is shown as being hollow, and the vibration motor 60 is positioned in the immediate vicinity of the front end 41 of the actuator in contact with the plunger 30. The vibration motor is a relatively small motor, with dimensions in the order of a few centimeters. The vibration motor can be designed as a motor with a weight 62 eccentrically mounted on the output shaft 61. In a suitable embodiment, use can be made of vibration motors as known for use in electric toothbrushes.

In the handle 21 is a battery 70, which provides electrical power to the motor 60. For the sake of simplicity, electrical wiring is not shown. The size of the battery (i.e. the type of the battery) is adapted to the voltage requirement of the motor 60 and to the dimensions of the handle 21. The handle 21 may be provided with a removable cover or the like to replace the battery 70. when it is empty, but it is not displayed. Alternatively, it is possible that the battery 70 is a rechargeable battery, and that the handle is provided with an electrical connector for connecting an external charger, or with a receiving coil plus an associated electronic circuit for wirelessly receiving electromagnetic energy around the to charge the battery, but that is also not shown.

For energizing the motor 60, the dispenser is provided with a switch 71, which can be operated by a user. Easy operation becomes possible if the user can operate this switch with the same hand that holds the dispenser and operates the operating mechanism 50, simultaneously with operating the operating mechanism 50. This advantage is achieved, for example, if the switch 71 is mounted in the handle 21, preferably at the rear of the handle 21 (i.e., on the side remote from the lever 51), as illustrated. Alternatively, the switch 71 could also be mounted on the front of the lever 51. If it is desired to prevent dust and the like from entering the switch 71, the switch 71 can be covered by a flexible sealing member, e.g. made of rubber or silicone.

The operation is as follows. The user places a cartridge 2 in the receiving space 24, and optionally a separate nozzle 25. He then brings the nozzle 25 to the place where the pasty mass is to be dispensed, and squeezes the lever 51 and the handle 21 together, thereby also pressing the switch 71, whereby the actuator 40 presses against the plunger 30, the plunger 30 presses against the cartridge 2, and the motor 60 is switched on. The motor generates a low-frequency vibration of the actuator 40, the frequency of which may be, for example, in the range of about 1 Hz to about 3000 Hz, although higher or lower frequencies are not excluded; in any case, the vibration is considerably less than ultrasonic. A practically suitable frequency is, for example, in the range of 50 to 150 Hz. The generated vibration is transmitted by the actuator 40 via the plunger 30 to the pasty mass pressed out of the cartridge by the plunger, which ultimately results in a viscosity reduction of that mass.

Figure 2 illustrates another dispenser 100 according to the present invention. The actuator 40 is provided on its rear side with a rod 46 which projects out of the housing 20 and is provided with a handle 47 at its rear end, in the example shown an annular handle. The actuator 40 is furthermore provided with a force member 48 which can exert on the actuator 40 a forward-looking force (i.e. a direction directed towards the nozzle 25). In the embodiment shown, that force member 48 is designed as a helical compression spring around the rod 46, which compression spring is supported on the one hand against a rear surface of the actuator 40 and on the other hand against a support surface 28 of the housing 20. Through the annular handle 47 pulling the rear end, the user can tension the spring 48.

The operating mechanism 150 in this embodiment comprises a brake to be operated by the user. This brake can be designed as a friction brake or as a ratchet. By pressing a push button the braking force is reduced and the spring presses harder. Since here the force required for squeezing out the pasty mass is supplied by the spring, and the user only needs to exert relatively little force to reduce the braking effect, the advantage is achieved that the user releases it with relatively little force of this mass can comfortably dose.

In the embodiment shown, the operating mechanism 150 comprises a brake body 151 with a brake shoe 152 at an upper end, which brake body 151 is slidably accommodated in a vertical direction in a chamber 153 in the handle 21, with a compression spring 154 between the brake body 151 and the bottom of said brake body 151. chamber 153. Under normal circumstances, the compression spring 154 presses the brake body 151 up against the actuator 40 with such a force that the resulting friction force is sufficient to counteract the pressure force of the spring 48 and to keep the actuator 40 still.

The operating mechanism 150 further comprises a push button 155 which can be slid horizontally in the handle 21, a key 156 of which extends through an opening 157 in the brake body 151. The key 156 has an inclined surface 158 on its underside, which cooperates with an inclined surface on the underside of said aperture 157. When the user presses the push button 155 and thus pushes the key 156 inward, the brake body 151 is pushed down a little bit, thereby reducing the upward pressing force of the brake shoe 152 against the actuator 40, so that in turn the frictional force decreases and the pressing force of the spring 48 becomes greater than that frictional force.

When the user releases the push button 155, it is pushed outwards by a return spring 160, whereby the pressing force of the brake shoe 152 against the actuator 40 is increased again.

It will be clear to a person skilled in the art that the invention is not limited to the exemplary embodiments discussed above, but that various variants and modifications are possible within the scope of the invention as defined in the appended claims.

For example, it is possible that the motor 60 is included in the plunger 30 instead of the actuator 40, which is illustrated in the embodiment 100 of Figure 2 but is also applicable in the embodiment 1 of Figure 1. It is also possible that the plunger and the actuator form an integrated whole.

Claims (8)

A dispenser (1; 100) for dispensing a viscous mass, comprising: a gun-shaped body (20) with a grip portion (21) and a barrel portion (22); a nozzle (25) disposed at an exit end (23) of the running portion (22); a receiving space (24) at said exit end (23) for receiving a cartridge (2) with said mass; a plunger (30) movably received in the running portion for urging said mass out of said cartridge through the nozzle; an actuator (40) displaceable in the running portion for displacing the plunger; an operating mechanism (50; 150) for operating a displacement of the actuator (40) by a user; a vibration motor (60) coupled to the plunger (30) or the actuator (40), which motor can be powered by a battery (70) to be placed in the handle (21); a switch (71) for switching the motor ON or OFF. The dispenser of claim 1, wherein the vibration motor (60) is mounted in or on the plunger (30). The dispenser of claim 1, wherein the vibration motor (60) is mounted in or on the actuator (40). The dispenser of claim 1, wherein the plunger (30) and the actuator (40) are formed as an integrated whole, and wherein the vibration motor (60) is mounted in or on that integrated whole. Dispenser according to any of the preceding claims 1-4, wherein the switch (71) is mounted in or on the handle (21). A dispenser according to any of the preceding claims 1-4, wherein the operating mechanism (50; 150) comprises a lever (51) or push button (155) displaceable relative to the handle (21), and wherein the switch (71) is mounted in or on said lever (51) respectively in or on said push button (155). Dispenser according to any of the preceding claims, wherein the operating mechanism (150) comprises a compression spring (48) for exerting a pressure force on the actuator (40), and wherein the operating mechanism (150) comprises a brake to be operated by the user . A dispenser according to claim 7, wherein the operating mechanism comprises a brake body (151) pressed by a compression spring (154) against the actuator (40) with a brake shoe (152) at an upper end; and wherein the operating mechanism (150) comprises a key (156) operable by a push button (155) slidable in the handle (21), which key extends through an opening (157) in the brake body (151), said key (156) has inclined surface (158) cooperating with an inclined surface of said opening (157).