APPLICATION OF A POROUS MATERIAL

Abstract

The present invention relates to a new application of a porous material. The porous material is composed of pore cavities and cavity walls surrounding the pore cavities, wherein the pore cavities of the porous material are three-dimensionally interconnected; the capillary force of the porous material is 5 Pa or more; and a contact angle between a surface of the cavity wall of the porous material and a liquid phase material circulating therein is less than 90. The porous material is applied as a microcirculation power source. The porous material is used in a circulation system as a microcirculation power source for providing material exchange. The porous material is used in a separation system as a microcirculation power source for providing material separation and movement. The porous material is used in a medical implant system as a microcirculation power source for providing tissue cell growth.

Claims

1. A porous material, comprising a plurality of pore cavities and cavity walls surrounding the pore cavities, wherein the pore cavities of the porous material are three-dimensionally interconnected; a capillary force of the porous material is 5 Pa or more; and a contact angle between a surface of the cavity wall of the porous material and a liquid phase material circulating therein is less than 90; the porous material is applied as a microcirculation power source.

2. A circulation system comprising a microcirculation power source providing a power source of material exchange, wherein the microcirculation power source is a porous material, and the porous material comprises a plurality of pore cavities and cavity walls surrounding the pore cavities, wherein the pore cavities of the porous material are three-dimensionally interconnected; a capillary force of the porous material is 5 Pa or more; and a contact angle between a surface of the cavity wall of the porous material and a liquid phase material circulating therein is less than 90.

3. A separation system comprising a microcirculation power source providing a power source of material separation and movement, wherein the microcirculation power source is a porous material, and the porous material comprises a plurality of pore cavities and cavity walls surrounding the pore cavities, wherein the pore cavities of the porous material are three-dimensionally interconnected; a capillary force of the porous material is 5 Pa or more:, and a contact angle between a surface of the cavity wall of the porous material and a liquid phase material circulating therein is less than 90.

4. The porous material according to claim 1, wherein the porous material is used in a medical implant system as a microcirculation power source for providing a power source of tissue cell growth.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] The present invention will be further described with the accompanying drawings and embodiments.

[0018] FIG. 1 is a schematic diagram of the capillary force test device designed based on GB5250-93.

[0019] FIG. 2 is a schematic diagram of experiment of the microcirculation formed by the capillary force conformation of the porous material of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0020] The detailed embodiments are given on the premise of the technical solutions of the present invention, but the protection scope of the present invention is not limited to the following, embodiments. It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention as defined by the appended claims, according to the common knowledge and/or common means in the field, and should be included in the scope of the present invention.

[0021] In FIG, 1, 1 is a clamping device, 2 is a porous material, 3 is a liquid phase material, 4 is a container for the liquid phase material 3, and 5 is an electronic balance.

[0022] According to the device shown in. FIG. 1, the capillary force of porous materials can be measured, the measuring processes are:

[0023] (1) The container 4 filled with the liquid phase material 3 is placed on the electronic balance 5 and the electronic balance 5 is reset;

[0024] (2) The porous material 2 is vertically fixed on the clamping device 1;

[0025] (3) By adjusting the clamping device 1, put the porous material 2 stretches into liquid level of the liquid phase material 3 for 1-2 mm, and then start the timer to measure timing;

[0026] (4) When the number of the reading of the electronic balance begins to become negative, that is, the number of the reading shows the quality of liquid phase material which the porous material 2 sucks from the liquid phase material 3;

[0027] (5) According to the formula (2), calculating the capillary force P.

P=M.sup.2/[2K(S).sup.2t](2)

[0028] Wherein, is the kinetic viscosity of the liquid phase material flowing through the porous material;

[0029] M is the quality of the liquid phase material sucked by the porous material;

[0030] K is the permeability of the porous material;

[0031] is the porosity of the porous material;

[0032] is the density of the liquid phase material flowing through the porous material;

[0033] S is the cross-sectional area of the porous material;

[0034] t is the time that the liquid medium takes for rising.

[0035] In FIG. 2, 6 is a porous material, 7 is a plastic pipe, the plastic pipe 7 is divided into two parts, a main pipe 7-1 and a branch pipe 7-2. The main pipe 7-1 is connected with the branch pipe 7-2, 7-3 is a linking part. The outer diameter of the porous material 6 is made according to the inner diameter of the main, pipe 7-1. The porous material 6 is put into the main pipe 7-1. 8 is a vessel, the liquid medium is contained in the vessel 8. 9 is a fixing seat for fixing the plastic pipe 7. The main pipe 7-1 of the plastic pipe 7 containing the porous material 6 is placed into the vessel 8. The porous material 6 is above a certain height, in the liquid medium, the top of the porous material 6 is located below the lower portion of the link part 7-3. When the porous material 6 has a capillary force, the liquid medium contained in the vessel 8 will be sucked into the porous material. When the capillary force is strong enough, the liquid medium will rise to the top of the porous material, above the liquid level and reaches the link part 7-3, and flows out of the branch pipe 7-2, and then flows into the vessel 8 to form circulation.

Embodiment 1

[0036] The porous material of the present embodiment is porous silicon carbide, the pores of which are three-dimensionally interconnected with a porosity of 70% and an average pore diameter of 1260 m. When the liquid phase material is deionized water, the capillary force at 20 C. is 5.2 Pa, which is calculated by using the device shown in FIG. 1 and is calculated by the formula (2). Using the same materials and processes of preparation of the porous silicon carbide to prepare a plane with the same state as cavity wall of the porous silicon carbide. With the help of the JY-82 contact angle measuring instrument, using drop method to test with droplet volume of 2 l at the test environment temperature of 20 C., the measured contact angle between the plane and deionized water is 88.7. The material is tested with the device shown in FIG. 2 and the porous material 6 is 40 mm above the deionized water level. The test shows that the water quickly rises to the top of the porous material 6, flows out of the branch pipe 7-2, and then flows into the vessel 8 to form continuous cyclic process. This kind of material is used in the microcirculation system part of the small-scale water treatment circulation system for exchange of the water to be treated and the treated water. The application shows that, this kind of porous silicon carbide, because of its capillary force up to 5.2 Pa, with a strong suction force, which becomes one of the power sources, accelerates the flow of water relative to the absence of porous silicon carbide. Further, the test shows that the flow rate through the porous silicon carbide is increased by 21% relative to that without the porous silicon carbide, thereby increasing the exchange efficiency, but also increasing the exchange volume to achieve energy saving.

Embodiment 2

[0037] The porous material of the present embodiment is porous quartz, the pores of which, are three-dimensionally interconnected with a porosity of 60% and an average pore diameter of 200 m. When the liquid medium is kerosene, the porous quartz is tested at 20 C. using the device shown in FIG. 1 and the formula (2) to calculate the capillary force up to 154 Pa. Using the same materials and processes of the preparation of the porous quartz to prepare a plane with the same state as cavity walls of the porous quartz. According to the test method and conditions of Embodiment 1 to test, the contact angle between the plane and kerosene is 50. The kerosene has good infiltration to such surface. The material is tested by the device shown in FIG. 2, and the porous material 6 is 50 mm above the kerosene level. The tests show that the kerosene quickly rises to the top of the porous material 6, flows out of the branch pipe 7-2, and then flows into the vessel 8 to form a continuous cyclic process. The material is used for kerosene filtration devices. Due to the capillary force of up to 154 Pa, with a strong suction force, it becomes one of the power sources. The power source accelerates the flow of kerosene containing solid impurity particles through the porous quartz, accelerating the separation of impurity particles from the kerosene containing impurity particles. The test results show that the separation efficiency increased by more than 32%.

Embodiment 3

[0038] The porous material of the present embodiment is porous tantalum and has two levels pore structure, classified by the material pore size. The pores within each level and the pores at different levels are three-dimensionally connected, with a total effective porosity of 80%. The pore size of the large pores is 400 m-600 m, with pores having an average pore diameter of 30 m on the cavity walls. When the medium is New Zealand white rabbit blood, the capillary force is up to 2190 Pa at 20 C., calculated by the device shown in FIG. 1 using formula (2). Using the same materials and processes of the preparation of the porous tantalum to prepare a same plane with the same state as cavity walls of the porous tantalum. According to the test method and conditions of Embodiment 1, the contact angle of the plane with New Zealand white rabbit blood is 70. New Zealand rabbit blood has good infiltration to the surface of the material. The material can be used as a bone implant material for repairing femur defect caused by the lesion in the femur tissue repair of New Zealand white rabbit's test.

[0039] Each animal organ, every tissue cell is provided by the microcirculation of oxygen, nourishment, transfer of energy, exchange of information, removal of carbon dioxide and metabolic waste. Once the microcirculation is in disorder, its corresponding tissue system or internal organs will be affected and can not perform normal function, which can easily to lead to aging, immune disorders and diseases. At this time, if this kind of microcirculation system can be provided as a power source, the blood and tissue fluid can flowed and exchange properly, which will overcome the microcirculation obstacle.

[0040] In the embodiment, due to the lesion of the original femur caused by poor microcirculation around the lesion, the porous tantalum is implanted into the rabbit femur as a bone implant material, due to the strong capillary force, the porous tantalum acts as a microcirculation power source, promoting the blood and tissue fluid exchange, accelerating the formation of microcirculation blood vessels, so as to promote smooth flow of microcirculation, promote the growth of bone cells, and accelerate the repair of bone tissues.

[0041] After 12 weeks of implantation, the examination results showed that the new bone grows into porous tantalum and closely combines with the porous tantalum. The surrounding tissue grows well, the microvascular is full as web-like, and the implantation effect is good.