KR820000700B1 - Piston for metering devices and a method for producing it - Google Patents

Abstract

Piston for metering devices is consisted of cylindrical core. made of glass, ceramic, and metal and tube, i.e., a covering layer made of polytetrafluoroethylene(PTFE) reinforced by 10 - 60 wt.% glass fibre or other deactive filler. Said tube is adhered to themal contractive core without adhesive and is grinded to fit into design dimension after cooling.

Description

Piston for Meter

The accompanying drawings illustrate the piston for the meter.

The present invention relates to a piston for a meter.

In order to accurately dispense the liquid from the reservoir, a metering device has long been used. Such a metering device is installed on a storage container, and is mainly composed of a mist suction valve, a discharge valve, and a discharge pipe that can slide in a glass cylinder. When the piston is slid into the cylinder to perform the suction stroke, a certain amount of liquid flows from the reservoir into the cylinder, and a certain amount of liquid sucked by the piston in the opposite direction of the ion is discharged to the discharge tube. Through the container will be. Thus, this type of metering device is substantially a piston piston metering pump.

This type of metering device is mainly used in chemical, industrial and drug laboratories. The liquid to be metered is a concentrated solution of chemically irritating reagents such as inorganic acids or concentrated solutions of alkali metal hydroxides.

The high concentrations, as well as the pronounced corrosiveness of the liquid being metered, tend to deposit in the metering cylinders, eliminating the big problem for this type of metering device. The only practically acceptable materials for all parts of the metering device in contact with the metered medium are glass, sintered ceramic materials and polytetrafluoroethylene (PTFE). Indeed, the cylinder of such a metering device has been made of glass in all cases for many years. However, it has long been known that the use of a metering piston made of glass or ceramic material in a cylinder made of glass is not suitable for high concentrations of alkalis, especially in the case of many media to be metered. In order to make glass modified pistons or plungers fit in the weighing cylinders, grinding should be carried out with a minimum tolerance.固 着). If the piston is tolerated by a relatively large error in the cylinder, it can certainly avoid the piston sticking to the cylinder for a longer time, but suction is inaccurate and accurate metering is impossible. It is also impossible to use grease (even silicon grease) because of the corrosiveness of the medium to be metered.

Indeed, the only material suitable for metering piston sliding surfaces is polytetrafluoroethylene (PTFE), which has been known to date, but the higher coefficient of thermal expansion of PTFE is higher than that of solid pistons made of PTFE. Because of its use is impossible. The metering device shall be able to be dried and disinfected in a sterilization vessel at a temperature of about 120 ° C.

In order to overcome this disadvantage, a proposal to make a piston of a ceramic core coated with PTFE, for example, as described in the prior art is described in German application 2,343,687. This coating can be made as shrink foil or in place by other means. Such coatings can only be made relatively thin due to the high coefficient of thermal expansion of PTFE, which is actually between 0.1 and 0.5 mm thick. In order to secure the PTFE coating on the glass surface or the ceramic surface sufficiently, spraying or brush coating or adhesive or primer should be used for coating.

However, pistons coated with PTFE in this manner are not resistant to a series of highly corrosive liquids, and in particular to aqueous sodium hydroxide solutions. This is because such a thin PTFE coating layer can never be made without pores. If such a piston is used to meter sodium hydroxide, sodium hydroxide will leak through these pores and destroy the adhesive, which will eventually cause the PTFE coating to detach or break in a short time. However, thick pore-free PTFE or solid PTFE pistons cannot be used because of their high thermal expansion, making them impossible to produce precise pistons. As described above, PTFE cannot be polished to have the required precision as a piston of the measuring device.

The use of PTFE shrink foil is particularly expensive and practically unusable. In addition, when mechanical durability (오랫동안 久 性) is required for a long time, such a foil (箔) is usually made by using an adhesive, but can not avoid the disadvantages described above. If shrink foil is used on a ceramic piston without adhesive, it is not possible to dry the piston in a general dryer where a temperature between about 110-115 ° C. is required. The shrink foil is weakened and thermally expanded so that the piston can no longer be used.

In view of this prior art, the present invention aims to provide a piston for use with the glass cylinders mentioned above, which can be used for all corrosive media for an indefinite period of time, without decomposing the glass or ceramic material, I) To provide a piston that can be used indefinitely for the measurement of alkali metal hydroxides. The piston is also mechanically durable and inexpensive to manufacture.

The metering piston of the present invention for achieving this object has the features as described in the claims.

Glass fiber reinforced polytetrafluoroethylene (GFPTFE), which is used as the coating layer of the metering piston, is about 20-50% lower depending on the degree of glass fiber filling than PTFE without the glass fiber filling. It has a coefficient of thermal expansion. Therefore, in the case of a normal piston diameter of about 10-100 mm, a 1-3 mm thick coating layer can be easily used. For this thickness layer no adhesive is required between the core surface of the piston of glass or ceramic and the inner surface of the piston coating layer. Therefore, irrespective of the principle of the applied method, it is possible to make a durable and safe coating on the piston core at such a thickness that has absolutely no through-holes. However, GFPTFE, which has a substantially lower coefficient of linear thermal expansion compared to unreinforced PTFE, is insufficient to produce a fully rigid metered piston coated with PTFE.

Another practical factor for creating a fully rigid piston is the fact that GFPTFE can be ground with the same precision as glass grinding, in contrast to non-reinforced PTFE. This results in a sufficient excess adhesion of the GFPTFE coating on the glass or ceramic core first, followed by other processing steps, and then a length that can be precisely polished by the same method used for glass pistons.

GFPTFE can be used as a material to make the cladding of the piston core into a thicker layer, so that preformed GFPTFE materials that can be attached by heat shrink can be used. The price of such a semi-finished product is about 70-80% or less of the price of PTFE shrink foil made in the prior art.

GFPTFE should normally contain no more than 60% by weight of glass fiber no less than 10% by weight.

If the glass fiber is less than 10% by weight, the coefficient of thermal expansion is so large that it inhibits the adhesion of the material to our piston core, and the coating cannot be polished precisely.

In the case where the glass fiber in GFPTFE is 60% by weight or more, the aqueous solution of sodium hydroxide is measured by this metering device, and the surface change action and the solidification effect as in the case of using the glass piston in the glass cylinder are generated.

According to another configuration of the invention, the coating of the metering piston is preferably made of GFPTFE reinforced with 20-30% by weight, in particular about 25% by weight, glass fibers.

The present invention is based on the basic principle of making a combination of a piston core with a relatively rigid tubing reinforced or filled, away from the conventional method of coating PTFE on the piston core in metering piston production.

In this respect, the reinforced PTFE new ube is made in advance as a semi-finished product, separate from the piston core, and is subsequently formed into one assembly by heat shrink.

Reinforced PTFE for this purpose is important to meet three conditions: (1) it must be chemically inert and stable, such as unreinforced PTFE, and (2) have a lower coefficient of thermal expansion than unreinforced PTFE. And (3) in contrast to unreinforced PTFE, should be polished to the same precision as glass.

These three properties consist of reinforced PTFE using the glass fibers according to the invention. However, comparable properties may also be made of other heavy agents or additives, such as glass powders, carbon fibers, graphite fibers, carbon powders, graphite powders or some other fibers or powdered high purity inorganic oxides or carbides.

Such modifications and variations of the present invention are technically equivalent and fall within the scope of the present invention. It has been found that GFPTFE is particularly preferred as a material for preparing metered piston coating layers in that it is a very satisfactory abrasive material comparable to chemical safety and abrasive property of glass.

In the case where the piston diameter is large, it is preferable to make the tube having an open cross section. Then, the glass core surrounded by the GFPTFE coated cross section of the working piston of the metering piston remains exposed to the cross section of the ceramic core core. Especially for pistons of large diameter (about 30-100 mm), this increases the thermal stability related to the size of the metering piston. The diffusion of the corrosive molecular component of the metering liquid at the interface between the core and the coating cannot be caused by any obstacle since the coating layer is in direct contact with the core, and no change of material occurs at the interface. In some cases, even though there are molecules that penetrate the interface radially through the recovery, if the thickness of the coating is about 1 mm, there is no concern because there is absolutely no hole therethrough.

In order to produce the piston, the semifinished product of GFPTFE, in particular its inner diameter, is generally about 1-8%, preferably 2-3% smaller than the outer diameter of the core, or the set diameter of the finished product of the piston ( It is preferable to use a tubular material which is slightly larger in outer diameter than 2), for example, 2-20%, preferably 5-15%. This semifinished product can be adhered to the core by heat shrink without the use of an adhesive. This shrinkage adhesion is clearly distinguished from the fact that the shrinkage of the shrinkage foil known in the prior art works by tissue replacement caused by heat in that it is pure heat shrinkage. In order to shrink-attach the GFPTFE tube to a glass core or ceramic core, the GFPTFE tube is cut to the desired coating length and heated uniformly to a temperature of preferably about 190-250 ° C. At this temperature the GFPTFE tubing attaches to the piston core at ambient temperature (15-30 °). After cooling, the GFPTFE coating layer can be polished precisely to a desired size, such as a glass piston.

The pistons thus produced are mechanically rigid and the precisely ground surfaces themselves are extremely resistant to damage and can be used for all media for long periods of time and do not corrode the materials used. In particular, this piston can be put into the glass cylinder without any problem even if it is used for a long time for the measurement of alkali metal hydroxide solution. Such weighing operation is impossible with the weighing apparatus known so far.

The metering piston according to the invention consists of a core 1 and a coating layer 2 as shown in the accompanying drawings. The lower surface of the cylindrical drawing is the working surface of the piston that defines the stroke capacity in the weighing cylinder. The GFPTFE coating layer 2 also consists of a tube open to the piston operating surface. Therefore, the smoothly ground working surface is made up of the open end face 3 of the core 1 and the end face of the GFPTFE coating layer 2 which surrounds it.

Claims (1)

A metered piston comprising a cylindrical core made of glass, ceramic or metal and a polytetrafluoroethylene (PTFE) coating layer, wherein the coating layer is reinforced with 10 to 60% by weight glass fiber or other inert filler. A tubular tube made of polytetrafluoroethylene, which is fixed to a heat-shrinkable core without adhesive and is polished to a design dimension after cooling. Meter for piston with glass cylinder

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