NO345534B1 - Dosing system for door handle - Google Patents

Description

Title: Dosing system for door openers

Field of the invention

The present invention generally relates to solutions for improving hygiene and reducing the spread of infection. More particularly, the invention relates to solutions for dosing disinfectant by hand when opening a door with a door handle. In addition, it also applies to a separate mechanism that prevents dosing when handling the door handle on the opposite side. Concretely, the invention relates to a dosing system and a door turner according to the independent claims.

State of the art

Improving hygiene and reducing the spread of infection are overall goals of significant importance both for health and the economy on both a small and large scale. In a globalized world with great mobility, this has become increasingly important; something recent pandemics have clearly demonstrated.

Traditional dosing solutions are often placed on the wall or on a stand - preferably strategically placed, but the users themselves must want to use them. The dosing solutions are available in both mechanical and electronic systems.

Surveys show that less than 10% of the population use disinfection in this way, unless there are special situations where someone is watching and making demands - typically in restaurant areas on cruise ships.

Surveys also show that only 60-70% of the Scandinavian population wash their hands when visiting the toilet in public places. Traditional dosing solutions are of little help in such situations where visitors can easily opt out of using disinfection.

Especially in areas where many people travel, and in places where there are large concentrations of people over time, good hand hygiene is important to avoid the spread of infection.

Traffic hubs such as airports and railway stations are highly exposed to the spread of infection. Shopping centres, schools, and not least hospitals and other health institutions are also at risk. The employees are often good at good hand hygiene, but it is far from the visitors.

In more closed areas with a concentration of people, the risk of infection is even greater. This can be on cruise ships, oil platforms or the like where a number of people are within a limited area for perhaps weeks. In the event of an outbreak of such installations, the entire installation must be closed and disinfected.

There are large cultural differences when it comes to hygiene in general and particularly when visiting the toilet, and ever-increasing internationalization increases the need for good solutions to limit the spread of infection.

Description of known patent documents

There are a large number of patents and patent applications that have tried to solve problems related to the spread of infection when using doors and door handles. The present invention differs from prior art in general and in particular in relation to existing patents, among other things as explained below.

The patent family "Method and apparatus for dispensing sanitizer fluid, opening doors and recording data pertaining to hand sanitization" comprising: WO 2017/193088/ AU2017261361A1, shows an invention with electronic control of the system. It presents a solution with sensors that give a signal to motors/pumps that dose. The solution is designed for use with sliding-opening doors. In other words, the mechanism and door are pushed outwards, and are not intended for standard door handles.

The patent application "Sanitizer Apparatus" US2018135332 relates to the spraying of door handles. True, a mechanical solution, but with a patent for a time delay so that the door handle is sprayed with disinfecting liquid after someone has operated the door handle. This solution has also been tried by others, but it was not well received in the market because the door handle was no longer tempting to operate. You also do not achieve an effect for those who do not wash their hands after going to the toilet.

The patent application "Door handle sanitizer" GB2549144 (A) describes a device that is attached to the door frame and activated when the door is closed. The device then provides a spray of disinfectant liquid to clean the door handle. The device is therefore not integrated into the door handle mechanism itself, and disinfects the door handle and not the hand.

The patent application "Sanitizer Apparatus", US2018135332 describes a solution that sprays disinfectant liquid on the door handle, and a mechanical solution that provides a time delay after the door handle is operated.

The patent "Method and apparatus for dispensing sanitizer fluid", US8505782 (B1) describes a solution with an additional lever on the door handle that can be operated together with the door handle so that you get disinfectant fluid on your hand and/or door handle.

The patent "Method and apparatus for dispensing sanitizer fluid", US8408423 (B1) describes a solution for passing disinfectant fluid through a special door handle.

The patent application "Hand Sanitizing Door Opener", US2012080451 (A1) describes a solution that limits access to the door handle so that disinfectant liquid is applied by moving the hand towards the door handle. Here, too, it is intended for a door handle that you push to open the door.

The patent "Controllable door handle sanitizer", WO2010028170 (A2) describes an electronic solution to disinfect the door handle.

The patent "A door handle including means for cleaning the users hand" GB2421897 (A) describes dosing through a special door handle.

There are a number of problems with solutions according to the state of the art related, among other things, to efficiency in terms of hygiene, ease of use, ergonomics, economy including lifetime costs, energy consumption and standardisation.

Summary of the invention

A general purpose of the invention is to solve problems with the state of the art as described above.

An overall aim to improve hygiene and to reduce the spread of infection in general.

A more specific purpose of the invention is to contribute to a greater proportion of the population having clean hands in general and after toilet visits in particular.

An essential purpose of the invention is to provide a user-friendly concept. The user deals with a door handle in the usual way, but will receive a dose of disinfectant on his hand which he will automatically, by intuition, rub over his hands.

Disinfection is not intended to replace hand washing with soap and water, but to be a supplement - and not least to disinfect the hands of those who do not use soap and water - and to disinfect the hands of those who have washed their hands, but who nevertheless have unclean hands due to e.g. operation of unclean door handles.

It is a purpose of the invention to provide a solution that does not need an external energy supply, e.g. in the form of batteries or mains connection.

A further purpose is the reuse of existing solutions, including in the form of standard doors and door knobs.

The invention relates, among other things, to a solution which means that dosing only takes place on the side on which the dosing device is mounted. Handling the handle from the opposite side should not cause dosing to occur.

The solutions according to the invention are suitable for use on doors in general and are particularly relevant for toilet doors.

The invention particularly relates to solutions with mechanical transmission of power/movements, but does not exclude electronic solutions where sensors define when dosing should take place and electric motors/valves that provide dosing.

Mechanical transmission of movements with the solution can be physical braces, rods, hoops, but can also be with wire or cords. It can also be pneumatic or hydraulic. The starting point for mechanical force in dosing solutions is that a person uses twisting force on a normal door handle.

Mechanical power can also come from other handle solutions, or push solutions, but comes from people who add this power – or animals for that matter.

The dosing unit has space for a container - bottle or bag, which is easy to replace. That is, disposable containers. However, this does not rule out filling solutions that will contribute to a more environmentally friendly system where less packaging is used.

On the other hand, this must be weighed against the risk of impurities from the filling side, and simplicity for the service personnel.

Disinfectant - or other type of agent, can be liquid, gel, foam or other forms suitable for this use and device.

Service and replacement/refilling of the disinfection container is intended to be done by service personnel who do service in such areas anyway and who preferably have the same service interval. This applies to refilling toilet paper, soap, paper towels and general cleaning.

It is proposed that the dosing system has a trigger mechanism which means that users who absolutely do not want a dose on their hands can avoid getting a dose on their hands by operating a button or lever.

There may be physical or psychological reasons why someone does not want/cannot use disinfectant, such as allergies or other reasons. Arrangements are made so that signs and information systems inform about the type of agent being dosed, and that dosing can be avoided with the above-mentioned solution.

A first aspect of the invention is twist pin devices for door openers comprising a first and a second door handle, where the twist pin devices comprise a rotation controller with a first and a second rotation controller part with respectively a first and a corresponding second part of a claw coupling, where the first and second rotation controller parts are arranged to be rigidly connected to the first and second door handles, respectively, but rotatably connected to each other, and wherein the first and second claw coupling parts can freely rotate a predefined angle of rotation relative to each other such that both rotation control parts rotate when the first door handle is depressed, but only the second rotation control part rotates when the second door handle is depressed.

The twist pin devices can comprise a twist pin in the form of a two-part strut, where the two strut parts are rigidly connected to each of their rotation control parts, but rotatably arranged in relation to each other.

The rotary controller can be arranged to transfer standard dimensions for twist pin with standard dimensions for door handles. The brace may comprise a square brace divided in two.

A second aspect of the invention is a dosing system for automatic dosing of disinfectant by hand to a user when operating a doorknob, where the dosing system comprises a doorknob comprising a first and a second door handle connected to twist pin devices as described above, a dosing device comprising a disinfectant container suitable for to contain the disinfectant, with a dosing pump for dosing the disinfectant to the user's hand upon operation of the first door handle, and power transmission means arranged to transmit the force applied to the first door handle from the user's hand, via the rotation of at least parts of the turn pin means, to the dosing pump for the dosage.

The power transmission devices may comprise mechanical power transmission devices that connect the twist pin devices to the dosing pump.

The power transmission devices may include at least one of the following types: stay, wire, string, pneumatic devices and hydraulic devices.

The dosing system can further comprise a release lever arranged at the dosing unit and operable by the user, where the release lever mechanically interacts with the power transmission devices so that the dosing pump is not operated when the first door handle is operated.

The release lever can be arranged so that it releases the power transmission element so that the dosing pump is not operated.

The power transmission devices may comprise an energy harvesting system comprising a first energy harvesting unit mechanically connected to the turning pin devices for harvesting electrical energy from the force applied to at least one of the handles, and where the energy harvesting unit is electrically connected to the dosing pump for transmitting power to contribute to its operation.

The dosing system may comprise the twist pin devices as described above.

The force transmission means arranged to transmit the force applied to the first door handle from the user's hand to the dosing pump may be connected to the first rotation control part.

The power transmission means may be connected to a torque arm rigidly connected to the first rotation control part.

The power transmission devices may comprise an energy harvesting system comprising a first energy harvesting unit mechanically connected to the first rotation controller part for harvesting electrical energy from the force applied to the first handle, and where the energy harvesting unit is electrically connected to the dosing pump for transmitting power to contribute to operation thereof.

The energy harvesting system may further comprise a second energy harvesting unit mechanically connected to the second rotation controller part for harvesting electrical energy from force applied to the second handle, where the energy harvesting unit is electrically connected to the dosing pump for transmission of power to contribute to its operation.

At least one of an energy source and an energy store, in addition to the energy harvesting units, can provide power to contribute to operation of the dosing pump.

The energy harvesting system may comprise an energy harvesting unit arranged to be driven by movement of the door leaf where the door turner is arranged.

Dosing system can include devices for manually controlled electronic disconnection of the dosing pump.

The means needed to solve the problems

The present invention achieves the goals set out above by twist pin devices for a door twister and a dosing system, as defined in the introduction to independent claims, with the characteristics of these.

A number of non-exhaustive embodiments, variants or alternatives of the invention are defined in the dependent claims.

The present invention achieves the goal set out above by a set of independent claims.

Brief description of the figures

The invention shall be explained in more detail with reference to the following figures, in which:

- Figure 1 shows a dosing system ready to be mounted on a door, where the system comprises a main part (1), a cover (2), a release lever (3), a disinfection container (4), a door handle (5).

- Figure 2 shows a schematic representation of an embodiment of the invention with a mechanical power transmission (6), a dosing pump (7), a pump piston (8) that presses against a dosing pump (7), a release lever (3), a rotation controller (9) and a connecting piston (10).

- Figure 3 shows a schematic representation of the main part (1) of an embodiment of the invention as shown in Figure 1 and Figure 2, where the main part (1) comprises a release lever (3), a power transmission (6), a connection piston (10), a locking spring (11), an extension spring (12), a roller wheel (13) and a locking mechanism (14).

- Figure 4 shows a detailed embodiment of a door twister with automatic disconnection of the door handle operated from the opposite side of the device (external in this description). The rotation controller (9) comprises a first/outer rotation control part (9b) and a second/inner rotation control part (9a) coordinatedly arranged so that by operating the second/outer door handle (5b), the first rotation control part (9a) will not transfer movement to the power transmission shown in Figure 2.

- Figure 5 shows a door twister comprising a first/inner door handle (5a) which, when operated, will rotate the first/inner rotation control part (9a), thereby transferring movement to the power transmission, and second/outer rotation control part (9b). Square bar (17) and door handle outside (5b) will follow the same rotation as door handle inside (5a). The figure also shows two harvesting units (18a, 18b).

Overview of the reference numbers that refer to the drawings

Detailed description of the invention with reference to the figures The invention shall be described in more detail in the following with reference to the drawings which show several examples of implementation.

The system is roughly arranged to work as described below with reference to figures 1-4.

Figure 1 shows a dosing system ready to be mounted on a door, where the system comprises a main part (1), a cover (2), a release lever (3), a disinfection container (4), a door handle (5). The disinfection container (4) is here covered by the cover (2) and arranged to contain a disinfectant.

The dosing system further comprises cooperating devices for dosing the disinfectant as described further on. When a user or "guest" uses the door handle (5) in the usual way to open the door by pressing the door handle (5) down, he receives a dose of disinfectant from the disinfectant container (4) on his hand - in this case on the back of his hand.

The disinfectant normally maintains a lower temperature than the surface of the back of the hand, and purely intuitively the user will use the other hand to rub the agent outwards.

The main part (1) of the dosing system with the release lever (3) is described in more detail below.

Figure 2 shows a schematic representation of an embodiment of the invention with a mechanical power transmission (6), a dosing pump (7), a pump piston (8) that presses against a dosing pump (7), a release lever (3), a rotation controller (9) and a connecting piston (10). When the user turns the door handle (5a) to open the door, movement is transmitted through the power transmission (6) - which can be a strut/wire/string - and which pulls the pump piston (8), which in turn presses the dosing pump (7) which is co-operatively mounted with the disinfectant container (4). The dosing pump (7) is normally supplied with the container (4) and is thus replaced every time the container (4) is changed.

The power transmission (6) is affected by the user operating the door handle (5a) on the same side as the dosing unit. The rotation controller (9) with a torque arm in which the power transmission (6) is fixed, will rotate equally with the rotation of the door handle (5a).

The power transmission (6) will pull the pump piston (8) as described above if the connecting piston (10) is not released. If for some reason you do not want to, or cannot, get disinfectant liquid on your hands, you can operate the release lever (3).

The disinfectant can be gel, foam or liquid and have different viscosities depending on the type and supplier. It may therefore be necessary to be able to adjust how tight the power transmission (6) should be. This is not shown in the illustrations, but can be designed as a sleeve with threads arranged where the power transmission (6) is attached to the pump piston (8) in a similar way to brake adjustment on a bicycle.

Figure 3 shows a schematic representation of the main part (1) of an embodiment of the invention as shown in Figure 1 and Figure 2, where the main part (1) comprises a release lever (3), a power transmission (6), a connection piston (10), a locking spring (11), an extension spring (12), a roller wheel (13) and a locking mechanism (14). with a mechanical lever that disengages the mechanical power transmission shown in figures 1 and 2. The locking spring (11) locks the connecting piston (10) when the disengagement lever (3) is not operated. When the release lever (3) is operated, the locking spring (11) will detach from the connection piston (10) which is then pressed against the extension spring (12) when the door handle (5) is operated, causing the power transmission (6) to press against the roller wheel (13). When the operation of the door handle ceases, the extension spring (12) will push the connecting piston (10) back and the locking spring (11) will regain its locking position. The release lever (3) has a locking mechanism (14) under the connection piston (10) which means that the release lasts until the door handle is operated to open the door. The release lever (3) is thus designed to push the locking spring (11) when depressed. Thus, the connection piston (10) will be able to yield when the power transmission (6) presses against the roller wheel (13) when operating the door handle (5), and the pump piston (8) will not have enough power to press the dosing pump (7).

When the door handle (5) is released, the extension spring (12) will ensure that the connecting piston (10) will slide back into place and the locking spring (11) will lock the connecting piston (10) so that the system is ready for new dosing for the next person who operates the door handle.

To ensure that the system works regardless of the time spent between operating the release lever (3) and operating the door handle (5), a locking system (16) has been integrated into the release lever (3). This locks until the power transmission (6) pushes on the connection piston (10) so that the release lever (3) detaches from the lock and returns to the starting point by means of a spring/gas damper (15).

This construction means that you can operate both the release lever (3) and the door handle (5) with just one hand, and makes it easy to carry luggage or other things in the other hand.

The other hand should then be freed to rub the agent over the hands as soon as one has released the door handle (5)

Figure 4 shows a detailed embodiment of a door twister with automatic disconnection of the door handle operated from the opposite side of the device. The rotation controller (9) comprises a first/outer rotation control part (9b) and a second/inner rotation control part (9a) coordinated so that when the second/outer door handle (5b) is operated, the first rotation control part (9a) will not transmit movement to the power transmission shown in figure 2. Rotation control (9) comprises two rotation control parts (9a,9b) which means that corresponding movement on the door handle from the opposite side of the door does not lead to dosing.

The first rotation controller part (9a) has a square pin that fits into most door handles on the market, a claw connection to the second rotation controller part (9b) which causes it to rotate together with the second rotation controller part (9a). The first rotation controller part (9a) has a torque arm which controls how far the power transmission (6) moves.

The second rotation control part (9b) has a square hole that fits the standard square rod (17) for lock boxes and a claw coupling that fits against the first rotation control part (9a), but so that it does not rotate the first rotation control part (9a) when operated from the opposite side of the device. This happens by the rotation controller parts (9a, 9b) engaging each other as a claw coupling with slack arranged so that the rotation controller parts (9a, 9b) can freely rotate relative to each other in a predefined rotation angle. The rotation control parts (9a, 9b) with the corresponding part of the claw coupling are arranged on each part of a two-part twist pin.

The door handles (5) and the rotation controller (9), possibly with a torque arm for the power transmission, will, after being pressed down, return to the starting point by means of a spring system in the associated lock box (not shown in the figures) - in the same way as usual when operating door twisters. The dosing system will then follow up and be ready for a new cycle. The claw coupling is arranged so that the claw coupling part of the first rotation controller part (9a) when the first door handle (5a) is pressed down from the aforementioned starting point will coordinately turn the second rotation controller part (5b) at its claw coupling part, while the predefined angle of rotation is dimensioned so that the first rotation controller part ( 9a) with associated door handle (5a) is not rotated when the other door handle (5b) is pressed down.

In the example above, the dosing unit has a mechanical power transmission (6) which initiates dosing. This can be done electronically with sensors and electric motors, powered by a connected fixed power supply, energy harvesting from human handling of the door handle/door, or using replaceable and/or rechargeable batteries.

Figure 5 shows a door twister comprising a first/inner door handle (5a) which, when operated, will rotate the first/inner rotation control part (9a), thereby transferring movement to the power transmission, and second/outer rotation control part (9b). Square bar (17) and door handle outside (5b) will follow the same rotation as door handle inside (5a). The embodiment in the figure further comprises an energy harvesting system with two energy harvesting units (18a, 18b) mounted against the torque arm of the respective rotation control part (9a) and (9b).

The energy harvesting units (18a, 18b) utilize the energy from operating both door handles, and will be able to provide enough energy to show service information on a display and/or, together with a battery, drive sensors and pumps to dose the agent.

Claims (18)

PATENT CLAIMS. 1. Twist pin devices (9, 17) for door openers comprising a first (5a) and a second door handle (5b), characterized in that the twist pin devices comprise a rotation controller (9) with a first (9a) and a second rotation controller part (9b) with respectively a first and a corresponding second part of a claw coupling, wherein the first (9a) and the second (9b) rotation control part are arranged to be rigidly connected to the first (5a) and the second (5b) door handle respectively, but rotatably connected to each other, and wherein the first and second claw coupling parts can freely rotate a predefined angle of rotation relative to each other so that both rotation control parts (9a, 9b) rotate when the first door handle (5a) is depressed, but only the second rotation control part (9b) rotates when the second door handle (5b) is pressed. 2. Twist pin devices according to claim 1, where the twist pin devices comprise a twist pin (17) in the form of a two-part strut, where the two strut parts are rigidly connected to their respective rotation control parts (9a, 9b), but rotatably arranged in relation to each other. 3. Turning pin devices according to claim 2, where the rotation controller (9) is arranged to transfer standard dimensions for turning pin (17) with standard dimensions for door handles (5). 4. Twist pin devices according to claim 2 or 3, where the rod comprises a square rod divided in two. 5. Dosing system for automatic dosing of disinfectant by hand to a user when operating a doorknob, where the dosing system includes: - a door twister comprising a first (5a) and a second door handle (5b) connected to twist pin devices (9, 17) according to one of the above claims; - a dosing device comprising a disinfectant container (4) suitable for containing the disinfectant, with a dosing pump (7) for dosing the disinfectant on the hand of the user when operating the first door handle (5a); and - power transmission devices (6) arranged to transfer the force applied to the first door handle (5a) from the user's hand, via the rotation of at least parts of the twist pin devices (9, 17), to the dosing pump (7) for dosing. 6. Dosing system according to one of the above claims, wherein the power transmission devices comprise mechanical power transmission devices (6) which connect the twist pin devices to the dosing pump (7). 7. Dosing system according to claim 6, where the power transmission devices (6) comprise at least one of the following types: stay, wire, string, pneumatic devices and hydraulic devices. 8. Dosing system according to one of claims 5 - 7, further comprising a release lever arranged at the dosing unit and operable by the user, where the release lever (3) mechanically interacts with the power transmission devices so that the dosing pump (7) is not operated when the first door handle (5a) is operated. 9. Dosing system according to claim 8, where the release lever (3) is arranged so that it releases the power transmission element so that the dosing pump (6) is not operated. 10. Dosing system according to claim 5, wherein the power transmission devices comprise an energy harvesting system comprising a first energy harvesting unit (18a) mechanically connected to the twist pin devices for harvesting electrical energy from the force applied to at least one of the handles (5a, 5b), and wherein the energy harvesting unit (18a) is electrically connected with the dosing pump (7) for transferring power to contribute to its operation. 11. Dosing system according to one of claims 5 - 10, where the twist pin devices are according to one of claims 1 - 3. 12. Dosing system according to claim 11, where the power transmission devices (6) arranged to transfer the force applied to the first door handle (5a) from the user's hand to the dosing pump (7) are connected to the first rotation control part (9a). 13. Dosing system according to claim 12, where the power transmission devices (6) are connected to a torque arm rigidly connected to the first rotation controller part (9a). 14. Dosing system according to claim 11, wherein the power transmission devices comprise an energy harvesting system comprising a first energy harvesting unit (18a) mechanically connected to the first rotation controller part (9a) for harvesting electrical energy from the force applied to the first handle (5a), and wherein the energy harvesting unit (18a) is electrically connected to the dosing pump (7) for the transmission of power to contribute to its operation. 15. Dosing system according to claim 14, wherein the energy harvesting system further comprises a second energy harvesting unit (18b) mechanically connected to the second rotation controller part (9b) for harvesting electrical energy from force applied to the second handle (5b), wherein the energy harvesting unit (18b) is electrically connected to the dosing pump (6) for transferring power to contribute to its operation. 16. Dosing system according to claim 14 or 15, where at least one of an energy source and an energy storage in addition to the energy harvesting units (18a, 18b) provides an effect to contribute to the operation of the dosing pump (7). 17. Dosing system according to claim one of claims 14 - 16, where the energy harvesting system comprises an energy harvesting unit (18a, 18b) arranged to be driven by movement of the door leaf where the door turner is arranged. 18. Dosing system according to one of claims 15 to 17, comprising devices for manually controlled electronic disconnection of the dosing pump (7).