The invention discloses a light and convenient pneumatic tea brick preparing device, including a work table, a supporting device provided at a bottom of the work table, a punching device provided at a top of the supporting device and a limiting device provided at a top of the work table. An upwardly open rectangular accommodating cavity is provided at the bottom of the work table. The supporting device includes a supporting component, the punching device includes a power component, a punching component and a waterproof component, and the punching component includes a punching block. In this device, a working bin for holding tea leaves is formed by the limiting block, the rectangular accommodating cavity and the punching block, and the tea leaves in the working bin are punched by the punching block to form a tea brick which can be ejected together with the limiting block.

A press apparatus for forming molded products is provided and includes a motive source and a press assembly in fluid communication with the motive source. The press assembly includes a press plate and a device configured to actuate axial movement of the press plate. A mold base is positioned within the press assembly and configured for engagement with the press plate. The mold base includes a plurality of mold cavities and each of the mold cavities includes a mold cavity aperture. Each of the mold cavity apertures is arranged in a pattern and configured to provide access to a molded product positioned in a mold cavity. A release assembly is configured for engagement with the mold base and has a plurality of release fingers, each extending from a base plate. The plurality of release fingers is arranged in a pattern that aligns with the pattern of the mold cavity apertures.

A slip casting mold is useful for producing a ceramic die cast part. The slip casting mold includes a first mold part with a first main part and a first filtration layer and comprising at least one second mold part with a second main part and a second filtration layer. The first main part is equipped with at least one first dewatering channel with at least one dewatering channel end that opens into a second dewatering channel within the second mold part or into a dewatering channel within an additional dewatering body in a casting position.

A slip casting mold is useful for producing a ceramic die cast part. The slip casting mold includes a first mold part with a first main part and a first filtration layer and comprising at least one second mold part with a second main part and a second filtration layer. The first main part is equipped with at least one first dewatering channel with at least one dewatering channel end that opens into a second dewatering channel within the second mold part or into a dewatering channel within an additional dewatering body in a casting position.

The process immerses a plurality of smaller solids in a liquid softening/solvent/bonding agent (i.e. water, oils, solvent or some other combination). This reagent reacts with the solids over a period of time so that when the cavity containing the solid/liquid mixture is compressed, the solids and any other additives (i.e. oatmeal, spices, other foreign objects, etc . . . ) are forced together and force the liquid softening/solvent/bonding agent out. The expelled liquids are removed from the solids and additives which are then allowed to dry/bond/fuse thereby forming a solid bond. Whereas there is prior art utilizing aspects of this process specifically in soap scrap bonding, this method is the only method of compressing solids that does not require electricity and where the disparate solid pieces and the bonding agent/liquid are all contained in one vessel that enable the solids to react with the liquids and then be compressed removing the bonding agent/liquid and leaving only the solids which can then form a permanent bond, all in one device (see FIG. 8: Novel Mould Assembly , FIG. 10—Mould Assembly Option, FIG. 12—Novel Mould Assembly with Option Plunger Design). Furthermore, this design can incorporate the collection and if desired recycling of the reagent within the mould itself (i.e. a hollow cavity in the plunger and if necessary a collection vessel attached to the cap and/or stabilizing base). Finally, the plunger design allows the device to be used with or without any mechanical aids to prevent it from binding during longitudinal movement during compression of the mould/plunger. This, first of all, simplifies the mechanics of the device and allows the mould to be used by young and old alike regardless of ability.

This device will have applications in many industries but especially the craft industry (i.e. cheese making and soap making).

Provided is a method for manufacturing a medical sponge for orthopedic treatment by unilateral pressing, which relates to compaction of medical sponges. The method includes a pressing machine that includes a bottom bracket, two vertical support rods, a middle support, a U-shaped support, a drive assembly and two film pressing assemblies. The two vertical support rods are fixed vertically on both ends of the bottom bracket, respectively. The middle support is fixedly arranged on a middle of an upper side of the bottom bracket, and the U-shaped support is fixedly arranged on a top of the middle support. The drive assembly is fixedly arranged on the U-shaped support. The two film pressing assemblies are fixedly arranged between two outer sides of the U-shaped support and the two vertical support rods, respectively.

Provided is a method for manufacturing a medical sponge for orthopedic treatment by unilateral pressing, which relates to compaction of medical sponges. The method includes a pressing machine that includes a bottom bracket, two vertical support rods, a middle support, a U-shaped support, a drive assembly and two film pressing assemblies. The two vertical support rods are fixed vertically on both ends of the bottom bracket, respectively. The middle support is fixedly arranged on a middle of an upper side of the bottom bracket, and the U-shaped support is fixedly arranged on a top of the middle support. The drive assembly is fixedly arranged on the U-shaped support. The two film pressing assemblies are fixedly arranged between two outer sides of the U-shaped support and the two vertical support rods, respectively.

Provided is a method for manufacturing a medical sponge for orthopedic treatment by unilateral pressing, which relates to compaction of medical sponges. The method includes a pressing machine that includes a bottom bracket, two vertical support rods, a middle support, a U-shaped support, a drive assembly and two film pressing assemblies. The two vertical support rods are fixed vertically on both ends of the bottom bracket, respectively. The middle support is fixedly arranged on a middle of an upper side of the bottom bracket, and the U-shaped support is fixedly arranged on a top of the middle support. The drive assembly is fixedly arranged on the U-shaped support. The two film pressing assemblies are fixedly arranged between two outer sides of the U-shaped support and the two vertical support rods, respectively.

Provided is a method for manufacturing a medical sponge for orthopedic treatment by unilateral pressing, which relates to compaction of medical sponges. The method includes a pressing machine that includes a bottom bracket, two vertical support rods, a middle support, a U-shaped support, a drive assembly and two film pressing assemblies. The two vertical support rods are fixed vertically on both ends of the bottom bracket, respectively. The middle support is fixedly arranged on a middle of an upper side of the bottom bracket, and the U-shaped support is fixedly arranged on a top of the middle support. The drive assembly is fixedly arranged on the U-shaped support. The two film pressing assemblies are fixedly arranged between two outer sides of the U-shaped support and the two vertical support rods, respectively.

Provided is a molded article that has both a low specific gravity and high rigidity and further has suppressed wrinkles and scrapes, and a manufacturing method for the same. Hence, provided is a press-molded article manufacturing method for press-molding a sheet-shaped molding substrate that is disposed in a cavity of a molding die and contains reinforcing fibers randomly dispersed in a matrix resin using a press molding machine provided with a molding die that is a convex molding die provided with a cavity formed between a concave mold for forming an opening of a molded article and a convex mold that matches with the concave, and has at least one surface (B) on which a pressure is loaded in a range of 0% to 70% of a pressure loaded on a surface (A) when the pressure loaded on the surface (A) from the press molding machine is 100% with respect to the surface (A) orthogonal to a direction of pressure applied to the molding die from the press molding machine, the press-molded article manufacturing method comprising: a shaping step (III) of loading a surface pressure of 1 MPa or more as an external pressure from the press molding machine to the surface (A); and a pressure holding step (IV) of setting a pressure loaded as an external pressure from the press molding machine on the molding substrate to 0.1 MPa or less without releasing the molding die after the shaping step (III).