EP4342575A1 - Mixing system set and method for producing a cleaning agent - Google Patents

Abstract

The invention relates to a mixing system set for producing several cleaning agents (9), comprising several separately stored components, which include a surfactant component (1), a solvent component (2), an acidic component (3), an alkaline component ( 4), and - a mixing device (7) which is designed and set up to dose and mix the several components depending on proportions predetermined for the respective cleaning agent (9) for the production of the respective cleaning agent (9), the mixing device (7) is designed to first meter and premix the solvent component (2) and surfactant component (1) and then meter the acidic component (3) and/or alkaline component (4) and mix it with the premix of solvent Component (2) and surfactant component (1) are to be mixed when the surfactant component (1) is used to produce one of the cleaning agents. Furthermore, the invention relates to a method for producing a cleaning agent based on a mixing system set that is used separately from one another a surfactant component (1), a solvent component (2), an acidic component (3), an alkaline component (4) and water (6), wherein first the solvent component (2) and surfactant component ( 1) are metered and premixed and the premixed solvent and surfactant components (2, 1) are then mixed with water (6).

Description

The invention relates to a mixing system set and a method for producing a cleaning agent. In particular, the invention relates to a mixing system set that is suitable for producing several cleaning agents and a method that is suitable for producing the various cleaning agents.

There are a variety of different cleaning products and types such as glass cleaners, sanitary cleaners, dishwashing liquids, all-purpose cleaners, floor cleaners, etc., which are available for purchase as products. Users are often unsure about which product is the right one for the respective application and often feel overwhelmed when making a selection. At the same time, the application concentration and type of application are often complicated and not clear for the user, so that there is a lot of uncertainty among users.

Most of the products available for purchase are not high concentrates and consist of 80 to 98% water and are packaged in plastic bottles. As an application solution, these products therefore only contain a low active content, which means that a lot of water is wasted and there is an unfavorable ratio of packaging and cleaning active ingredient(s). The plastic bottles are often only used once or rarely by the user and then thrown away after a while. However, they are often only offered in larger packaging. This leads to the user throwing away chemicals and plastic unnecessarily.

With a mixing system set consisting of several components, many types of cleaning agents can be mixed with water. However, not all components can be easily mixed and can form lumps. The formation of such lumps must be prevented in order to ensure easy handling of such a mixing system set.

The invention therefore faces the problem of providing a variety of cleaning agents with a reduction in plastic waste and product diversity as well as a cleaning performance adapted to user needs.

According to the invention, this problem is solved by a mixing system set with the features of patent claim 1 and a method with the features of patent claim 9. Advantageous refinements and further developments of the invention result from the following subclaims.

The advantages that can be achieved with the invention are that several, a large number or at least ten of the most commonly used cleaning agents can be easily produced on site by the user with as few components as possible. A need-based production of cleaning agents and use is provided. This allows a reduction in plastic waste through reusable containers and a reduction in product variety by simplifying the offering and creating transparency.

The user can produce a quantity of the cleaning agent they want, which is required individually, for example depending on the size and furnishings of the apartment, hobbies, car, etc. In addition, there is no need to transport water. It is also possible to eliminate the need for preservatives because the cleaning agents can be made fresh. They do not need to be preserved for months of storage. Furthermore, it is possible to eliminate the need for stabilizers because the cleaning agents are used directly. The use of stabilizers, which are normally intended to keep the cleaning agent components homogeneously in solution, is not necessary.

• mehrere getrennt voneinander gelagerte Komponenten, die eine Tensid-Komponente, eine Lösemittel-Komponente, eine saure Komponente, eine alkalische Komponente umfassen, und
• eine Mischvorrichtung, die ausgebildet und eingerichtet ist, die mehreren Komponenten in Abhängigkeit von für das jeweilige Reinigungsmittel vorbestimmten Anteilen zur Herstellung des jeweiligen Reinigungsmittels zu dosieren und zu mischen, wobei die Mischvorrichtung ausgebildet ist, zuerst die Lösemittel-Komponente und Tensid-Komponente zu dosieren und vorzumischen und anschließend die saure Komponente und/oder alkalische Komponente zu dosieren und mit der Vormischung aus Lösemittel-Komponente und Tensid-Komponente zu mischen, wenn die Tensid-Komponente zu Herstellung eines der Reinigungsmittel verwendet wird.

The invention relates to a mixing system set for producing several cleaning agents, comprising

• several components stored separately from one another, which include a surfactant component, a solvent component, an acidic component, an alkaline component, and
• a mixing device which is designed and set up to dose and mix the several components depending on proportions predetermined for the respective cleaning agent for the production of the respective cleaning agent, the mixing device being designed to first dose the solvent component and surfactant component and premix and then meter the acidic component and / or alkaline component and mix it with the premix of solvent component and surfactant component if the surfactant component is used to produce one of the cleaning agents.

Most cleaning agents can be produced with the mixing system set consisting of at least four components and, if necessary, water for dilution. The water is preferably available on site in the user's household or business, but it can also be part of the mixing system set. The cleaning agents are preferably so-called household cleaners, even if they can be used in the commercial sector. The four essential components are the surfactant component, the solvent component, the acidic component and the alkaline component. The mixing system set, for example, has the four essential components separated from each other in containers such as cartridges or containers.

Each of the four components is preferably liquid and preferably contains water. Each of the components is preferably a concentrate. Therefore, the user only needs to transport the components in highly concentrated form from the place of purchase to the desired place of use. This saves packaging waste.

The fact that the mixing device first doses the surfactant component and the solvent component together and the resulting premix is then mixed with water, the acidic component and/or alkaline component prevents the surfactant component from forming gel lumps when mixed with water , which practically no longer dissolve or only dissolve very slowly. This further prevents the mixing device from becoming clogged. In addition, using the mixing device provides safe application through automatic mixing. This means that the user does not come into contact with the chemical compounds of the components.

The predetermined proportions of the components preferably depend on the type of cleaning agent to be produced desired by the user. Depending on the type of cleaning agent to be produced, proportions of the components can also be zero. This means that not all cleaning agents to be produced have to contain all four of the above components. The mixing device is preferably designed to meter the surfactant component only in combination with the solvent component. This means that every cleaning agent produced, if it contains the surfactant component, also contains the solvent component. The dosage or use of the solvent component is preferably independent of the use of the surfactant component, so that a cleaning agent produced can contain the solvent component but be surfactant component-free.

In a preferred embodiment, a mixing ratio of the surfactant component to the solvent component is from 10 to 1 to 1 to 10, preferably 5 to 1 to 1 to 5, more preferably from 5 to 1 to 1 to 1. This also ensures good cleaning performance of the cleaning agent produced is achieved without the formation of gel lumps.

The mixing device preferably has a mixing section, with each of the several components being assigned a dosing point on the mixing section and a pump for dosing the respective component. The mixing device preferably has a control device which is designed to control the pumps assigned to the respective components at a predetermined time. This ensures an advantageous mixing sequence of the components.

In a preferred embodiment, the dosing point assigned to the solvent component lies before the dosing point assigned to the surfactant component on the mixing section. The control device is preferably set up and designed to meter the solvent component in a period of time that begins at a time before the metering of the surfactant component and ends at a further point in time after the metering of the surfactant component has ended. This is achieved by controlling the pump assigned to the respective component. This ensures that the surfactant component and the solvent component are dosed at the same time. This prevents the surfactant component from just mixing with water and forming gel clumps.

In a preferred embodiment, the control device is set up and designed to start metering water into the mixing section by activating its associated pumps at a time that lies before the metering of the solvent component and the surfactant component. The dosing point assigned to the water is preferably behind the dosing point assigned to the solvent component and behind the dosing point assigned to the surfactant component on the mixing section. This prevents the surfactant component from forming gel lumps when mixed with water.

The dosing point assigned to the acidic component and/or the dosing point assigned to the alkaline component is preferably arranged behind the dosing point assigned to the water on the mixing section. As a result, the mixture of the surfactant component and the solvent component is already pre-diluted with water when the acidic and/or alkaline component(s) are metered into the mixing section.

In a preferred embodiment, the delivery rates and/or the timing of the pumps is or are the same. Alternatively, the delivery rates and/or the timing of the pumps are preferably different. The settings of the delivery rates and/or timing of the pumps are preferably selected in such a way that the mixing ratio of the components to one another that is predetermined for the respective cleaning agent to be produced is guaranteed.

Depending on a predetermined mixing ratio of the components, the cleaning agent produced is preferably a grill cleaner, oven cleaner, kitchen and/or power cleaner, floor cleaner, all-purpose cleaner, hand dishwashing liquid, glass cleaner, toilet cleaner, bathroom cleaner or descaler.

The mixing system set preferably also has two empty containers if it has the mixing device. One container is preferably suitable for filling with water, while the other container is preferably suitable for filling with water using the four to accommodate cleaning agents manufactured with essential and, if necessary, optional components. The components, which are stored separately from one another, are preferably housed in containers such as cartridges or containers in the mixing system set. The mixing device is preferably designed and set up to automatically fill the cleaning agent produced after mixing the intended components into the container provided for this purpose.

In a preferred embodiment, the surfactant component has a mixture of nonionic and anionic surfactants. Optionally, the surfactant component also contains amphoteric surfactants and biosurfactants. The surfactant component is more preferably a mixture of nonionic and anionic surfactants with solvent and possibly other auxiliary substances, whereby amphoteric surfactants and biosurfactants can optionally also be included. In a preferred embodiment, the surfactant component contains sodium lauryl ether sulfate, APG (alkyl polyglucoside) rhamnolipid, amine oxide, butoxydiglycol, perfume, enzyme and water. In the mixing system set, the surfactant component preferably represents a surfactant base for a hand dishwashing liquid, a grill cleaner, an oven cleaner and a bathroom cleaner. It also preferably represents a co-base for a kitchen/grill cleaner, a floor cleaner and an all-purpose cleaner.

The solvent component preferably has a mixture of a low-boiling solvent and a high-boiling solvent, which contains a maximum of 20% by weight of the amount of the low-boiling solvent. The low-boiling solvent is, for example, ethanol and/or isopropanol. The high-boiling solvent is, for example, propylene glycol. Optionally, the solvent component can contain further auxiliary substances and a surfactant. In a preferred embodiment, the solvent component contains ethanol, propylene glycol monobutyl ether, sodium lauryl ether sulfate and water. In the mixing system set, the solvent component preferably represents a base for a glass cleaner. It also preferably represents a co-base for a hand dishwashing liquid and a solubilizer for the surfactant component.

In a preferred embodiment, the acidic component has a mixture of at least one organic acid and at least one complexing agent. The at least organic acid is preferably citric acid, lactic acid and/or maleic acid. The at least one complexing agent is preferably phosphonic acid and/or one or more aminocarboxylates. The acidic component preferably contains lactic acid, citric acid, tetrasodium glutamate diacetate, for example GLDA 47 S (Aako, Leusden, Netherlands) in the form of an acid, phosphonic acid and water. In the mixing system set, the acidic component preferably represents a base for a descaler, a bathroom cleaner and a toilet cleaner. It also preferably represents a co-base for an oven cleaner, a grill cleaner, a kitchen power cleaner, a floor cleaner and an all-purpose cleaner.

In a preferred embodiment, the alkaline component has an alkali carrier. The alkali carrier preferably comprises sodium hydroxide solution, potassium hydroxide solution, monoethanolamine and/or one or more carbonates. More preferably, the alkaline component has a mixture of alkali carriers such as caustic soda, potassium hydroxide, monoethanolamine and/or carbonates with other auxiliaries such as complexing agents or surfactants. In a preferred embodiment, the alkaline component contains monoethanolamine, potassium hydroxide, sodium hydroxide, gluconate (gluconic acid), phosphonate, amine oxide and water. In the mixing system set, the alkaline component preferably represents a base for a grill cleaner and an oven cleaner. It also preferably represents a co-base for a bathroom cleaner, a toilet cleaner, a kitchen power cleaner, a floor cleaner and an all-purpose cleaner.

The invention further relates to a method for producing a cleaning agent based on a mixing system set, which separately comprises a surfactant component, a solvent component, an acidic component, an alkaline component and water, with the solvent component and surfactant component being added first. Components are metered and premixed and the premixed solvent and surfactant components are then mixed with water.

Embodiments and advantages described for the mixing system set apply to the method accordingly.

The process can be carried out by the user by hand or using the mixing device.

Fig. 1

eine skizzierte Darstellung eines erfindungsgemäßen Mischsystem-Sets; und

Fig. 2

eine skizzierte Teil-Darstellung des in Fig. 1 gezeigten Mischsystem-Sets.

An exemplary embodiment of the invention is shown purely schematically in the drawings and is described in more detail below. It shows schematically and not to scale

Fig. 1

a sketched representation of a mixing system set according to the invention; and

Fig. 2

a sketched partial representation of the in Fig. 1 Mixing system sets shown.

Fig. 1 shows a mixing system set according to the invention. The mixing system set has a surfactant component 1, a solvent component 2, an acidic component 3 and an alkaline component 4 separately from one another. The surfactant component 1 contains a mixture of nonionic and anionic surfactants, which also optionally contains amphoteric surfactants and biosurfactants. The solvent component 2 has a mixture of a low-boiling solvent such as ethanol and / or isopropanol and a high-boiling solvent such as propylene glycol, which contains a maximum of 20% of the amount of low boiling solvent is contained. The acidic component 3 has a mixture of at least one organic acid and at least one complexing agent, the at least organic acid being, for example, citric acid, lactic acid and/or maleic acid and the at least one complexing agent preferably being phosphonic acid and/or one or more aminocarboxylates. The alkaline component 4 has an alkali carrier which has, for example, sodium hydroxide solution, potassium hydroxide solution, monoethanolamine and/or one or more carbonates. The mixing system set also has a container for filling with water 6, a container into which the cleaning agent 9 to be produced is filled, and a mixing device 7 for mixing the surfactant component 1, the solvent component 2, the acidic component 3, etc alkaline component 4 and water 6 in a predetermined mixing ratio or predetermined proportions, which depends on the cleaning agent 9 to be produced. The mixing system set has a base 8 to ensure stability.

Fig. 2 shows a sketched partial representation of the in Fig. 1 Mixing system sets shown. Part of the mixing device 7 of the mixing system set is shown, in particular a mixing section 5 of the mixing device 7. The mixing device has a mixing section 5, with a flow direction of the dosages being indicated by an arrow. Each of the several components, ie the surfactant component 1, the solvent component 2, the acidic component 3, the alkaline component 4 and water 6, is a metering point 1', 2', 3', 4', 6' on the mixing section 5 and a respective pump (not shown) assigned for dosing the respective component. The dosing point 2' assigned to the solvent component 2 is in front of the dosing point 1' assigned to the surfactant component 1 on the mixing section 5. The dosing point 6' assigned to the water 6 is behind the dosing point 2' assigned to the solvent component 2 and behind that The dosing point 1' assigned to the surfactant component 1 on the mixing section 5. The dosing point 3' assigned to the acidic component 3 is behind the dosing point 6' assigned to the water 6 on the mixing section 5, and the dosing point 4' assigned to the alkaline component 4 is behind that Dosing point 3' assigned to the acidic component 3 on the mixing section 5.

Furthermore, the invention is described in more detail in the following example.

Example

A mixing system set according to the invention has the surfactant component, the solvent component, the acidic component and alkaline component separately from one another. The surfactant component contains 60.00 wt.% sodium lauryl ether sulfate in PG (propylene glycol), 20.00 wt.% APG rhamnolipid, 8.00 wt.% amine oxide (30%) (<2.5 active%), 5.00% by weight buthoxydiglycol, 1.00% by weight perfume, 1.00% by weight enzyme and water ad 100. The solvent component contains 90.00% by weight of ethanol, 8.00% by weight of propylene glycol monobutyl ether, 2.00% by weight of sodium lauryl ether sulfate in BG (butylene glycol) and water ad 100. The acidic component contains 50.00 % by weight lactic acid, 20.00% by weight citric acid, 7.00% by weight GLDA 47 S (acid), 3.00% by weight phosphonic acid and water ad 100. The alkaline component contains component 40.00 % by weight of monoethanolamine, 20.00% by weight of potassium hydroxide 45% / sodium hydroxide 50%, 5.00% by weight of gluconate (glyconic acid), 3.00% by weight of phosphonate, 6.00% by weight of amine oxide (30%) and water ad 100.

The recipes of this mixing system set for high concentrates with a very good performance profile are given as follows in Table 1: Table 1 Recipes Surfactant component (proportion in wt.%) Solvent component (proportion in wt.%) acidic component (proportion in wt.%) alkaline component (proportion in wt.%) Sum of components (% by weight) Water (Vol%) Grill cleaner 7 2 0 30 39 61 Oven cleaner 7 3 0 20 30 70 Kitchen/Power Cleaner 5 5 2 5 17 83 Floor cleaner 6 5 5 10 26 74 All-purpose cleaner 6 5 5 15 31 69 Hand dishwashing liquid 25 6 2 2 35 65 Glass cleaner 0 4 0 0 4 96 Toilet cleaner 3 5 30 0 38 62 Bathroom cleaner 7 5 20 0 32 68 Descaler 0 0 50 0 50 50

Reference symbol list

1

Surfactant component

1'

Dosing point

2

Solvent component

2'

Dosing point

3

acidic component

3'

Dosing point

4

alkaline component

4'

Dosing point

5

Mixing section

6

Water

6`

Dosing point

7

Mixing device

8th

Base

9

cleaning supplies

Claims (9)

Mixing system set for producing several cleaning agents (9), comprising - several components stored separately from one another, which include a surfactant component (1), a solvent component (2), an acidic component (3), an alkaline component (4), and - a mixing device (7), which is designed and set up to dose and mix the several components depending on proportions predetermined for the respective cleaning agent (9) for the production of the respective cleaning agent (9), the mixing device (7) being designed , first to meter and premix the solvent component (2) and surfactant component (1) and then to meter the acidic component (3) and / or alkaline component (4) and with the premix of solvent component (2) and To mix surfactant component (1) if the surfactant component (1) is used to produce one of the cleaning agents. Mixing system set according to claim 1, characterized in that a mixing ratio of the surfactant component (1) to the solvent component (2) is from 10 to 1 to 1 to 10, preferably 5 to 1 to 1 to 5, more preferably from 5 to 1 to 1 to 1 is. Mixing system set according to claim 1 or 2, characterized in that the mixing device (7) has a mixing section (5), each of the several components having a dosing point (1', 2', 3', 4', 6') on the mixing section (5) and a pump is assigned for metering the respective component, and the mixing device (7) has a control device which is designed to control the pumps assigned to the respective components at a respective predetermined time. Mixing system set according to claim 3, characterized in that the dosing point (2 ') assigned to the solvent component (2) is located in front of the dosing point (1') assigned to the surfactant component (1) on the mixing section (5) and the control device is set up and designed to dose the solvent component (2) in a period of time that begins at a time before the dosing of the surfactant component (1) and at a further time after the dosing of the surfactant component (1 ) ends. Mixing system set according to one of the preceding claims 3 or 4, characterized in that it further comprises water (6) and the dosing point (6`) assigned to the water (6) is behind that assigned to the solvent component (2). Dosing point (2 ') and behind the dosing point (1') assigned to the surfactant component (1) is arranged on the mixing section (5). Mixing system set according to claim 5, characterized in that the dosing point (3 ') assigned to the acidic component (3) and / or the dosing point (4') assigned to the alkaline component (4) is behind the water (6) assigned dosing point (6 ') is arranged on the mixing section (5). Mixing system set according to one of the preceding claims 3 to 6, characterized in that the delivery rates and / or the timing of the pumps is or are the same or different. Mixing system set according to one of the preceding claims, characterized in that the cleaning agent (9) produced, depending on predetermined mixing ratios of the components, is a grill cleaner, oven cleaner, kitchen and/or power cleaner, floor cleaner, all-purpose cleaner, hand dishwashing liquid, glass cleaner, toilet cleaner, bathroom cleaner or Descaler is. Method for producing a cleaning agent based on a mixing system set, which separately comprises a surfactant component (1), a solvent component (2), an acidic component (3), an alkaline component (4) and water (6). , characterized in that first the solvent component (2) and surfactant component (1) are metered and premixed and the premixed solvent (2) and surfactant components (2, 1) are then mixed with water (6).

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