IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0623901
(2001-12-18)
|
우선권정보 |
FR-0000246 (1999-01-02) |
국제출원번호 |
PCT/FR00/00054
(2000-01-12)
|
발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
4 인용 특허 :
12 |
초록
▼
The invention proposes an apparatus (10) comprising a casing (12, 20, 22) which has a wall (24) arranged to be coupled in rotation to a driving shaft, a turbine wheel (30) rotatable with a hub (34) which is arranged to be coupled in rotation to a driven shaft, a generally radially oriented piston (5
The invention proposes an apparatus (10) comprising a casing (12, 20, 22) which has a wall (24) arranged to be coupled in rotation to a driving shaft, a turbine wheel (30) rotatable with a hub (34) which is arranged to be coupled in rotation to a driven shaft, a generally radially oriented piston (58) which is movable axially and coupled in rotation to the casing, and an annular friction disc (74), oriented generally radially and carrying two annular friction liners (76) which are adapted to be gripped axially by the piston (58) between, respectively, itself and the inner face (73), in facing relationship with it, of the radial wall (24) of the casing; the friction disc (74) is coupled at its radially inner periphery (94) to the hub (34) of the turbine (30); the piston (58) has means (100) at its radially outer periphery for meshing with a radially outer peripheral portion (26, 102) of the casing (22).
대표청구항
▼
The invention proposes an apparatus (10) comprising a casing (12, 20, 22) which has a wall (24) arranged to be coupled in rotation to a driving shaft, a turbine wheel (30) rotatable with a hub (34) which is arranged to be coupled in rotation to a driven shaft, a generally radially oriented piston (5
The invention proposes an apparatus (10) comprising a casing (12, 20, 22) which has a wall (24) arranged to be coupled in rotation to a driving shaft, a turbine wheel (30) rotatable with a hub (34) which is arranged to be coupled in rotation to a driven shaft, a generally radially oriented piston (58) which is movable axially and coupled in rotation to the casing, and an annular friction disc (74), oriented generally radially and carrying two annular friction liners (76) which are adapted to be gripped axially by the piston (58) between, respectively, itself and the inner face (73), in facing relationship with it, of the radial wall (24) of the casing; the friction disc (74) is coupled at its radially inner periphery (94) to the hub (34) of the turbine (30); the piston (58) has means (100) at its radially outer periphery for meshing with a radially outer peripheral portion (26, 102) of the casing (22). the shank (4), an entire cross-sectional recessed surface (11) of each entrain groove (5) being larger than an entire cross-sectional outer surface (10) of each of groove-forming rest webs (6), and a mean rest cross-sectional area (A'), which is measured within an axial section of the drilling tool having a length at least equal to a product of a natural logarithm base and a stem diameter (e×D), deviating from a mean rest cross-sectional area (A) along the entire length of the drilling tool (1) maximum by 20%. 2. A rock drilling tool according to claim 1, wherein the mean rest cross-sectional area (A') in the region of the shank (4) is at most equal to the mean cross-sectional area (A') of the stem (2). 3. A rock drilling tool according to claim 1, wherein a length (N) of an arc of at least one entrain groove (5), which is measured in an arithmetic center of a radial engagement depth (T), of the groove, is greater than a maximum length (R) of an arc of a rest web (6). 4. A rock drilling tool according to claim 1, wherein the entrain grooves (5) are uniformly arranged over a shank circumference. 5. A rock drilling tool according to claim 1, wherein the plurality of entrain grooves (5) consists of four grooves. 6. A rock drilling tool according to claim 1, wherein the stem (2) is formed as a cylindrical smooth body. 7. A rock drilling tool according to claim 1, wherein an end of the washing fluid bore (7) is spaced from the entrain grooves (5) by a distance (x) smaller than the product of the natural logarithm base and the stem diameter (e×D). 8. A rock drilling tool according to claim 7, wherein the distance (x) between the end of the washing fluid bore (7) and the entrain grooves (5) is longer than half of the stem diameter (D). 9. A rock drilling tool according to claim 1, further comprising a radially extending band (9) provided in a transition region between the stem (2) and the shank (4). 10. A rock drilling tool according to claim 9, wherein the band (9) is located adjacent to one of a transverse bore (8) connecting the washing fluid bore (7) with outside, and an end of the washing fluid bore. trieving the collected soil sample from the sampling barrel without the assistance of securing any handle to the cartridge. 2. The cartridge of claim 1 wherein the height of the first lid is determined based on how far the ejector is to be pushed back into the first lid while collecting the soil sample. 3. The cartridge of claim 2 wherein the sampling barrel has a stopper concentrically located with the ejector inside the sampling barrel stopping the ejector to be pushed beyond a predetermined point. 4. A method for obtaining a soil sample using a cylindrical sampling barrel, the method comprising: securing a first lid to a first threaded connection on the sampling barrel at a first side of a holder of the sampling barrel, the holder having a bigger diameter than that of the sampling barrel, the first lid having a concentrically located nipple component with a receptive hole in the middle of the top of the nipple component with a predetermined depth; connecting an extended handle to the nipple component through a locking mechanism for locking the extended handle onto the first lid; inserting, using the extended handle, the sampling barrel into the soil for collecting the soil sample, wherein the soil sample pushes a rod-like ejector with a disk-like plunger inside the sampling barrel toward the first lid; pulling the sampling barrel out from the soil; securing a second lid to a second threaded connection on the sampling barrel at a second side of the holder to seal the soil sample in the sampling barrel after the sampling barrel is pulled using a septum positioned inside the second lid; unlocking the extended handle from the first lid; transporting the soil sample inside the sample barrel sealed with the first and second lids to a predetermined location for retrieving same; removing the second lid from the sampling barrel; removing the first lid from the sampling barrel; reversing the removed first lid to position the receptive hole to hold the ejector; and pushing the soil sample out from the sampling barrel by exerting force on a rim of the reversed first lid to press the ejector, wherein the pressed ejector pushes the soil sample out from the sampling barrel without the assistance of securing any handle to the sampling barrel. 5. The method of claim 4 further comprising sealing the sampling barrel with the second lid with sealing tapes before the sampling barrel is transported. 6. The method of claim 4 further comprising labeling the sampling barrel before the sampling barrel is transported. 7. A cartridge for extracting and preserving a soil sample, the cartridge comprising: a cylindrical sampling barrel for insertion into soil for collecting a soil sample; a guiding passage connected at a first end of the sampling barrel and being coaxial with the sampling barrel for hosting a rod-like ejector, the ejector being connected to a disk-like plunger through an internal taper having a conical surface, the diameter of the guiding passage being substantially smaller than that of the sampling barrel, and the rod-like ejector having an o-ring therearound to minimize the space between the ejector and the guiding passage; a holder on the periphery of the cartridge and around the first end of the sampling barrel; a first lid securable to a first threaded connection on the cartridge at a first side of the holder, the first lid having a concentrically located nipple component with a receptive hole in the middle of the top of the nipple component with a predetermined depth, the nipple component further having a locking slot for locking a detachable handle tool onto the first lid; and a second lid securable to a second threaded connection on the cartridge at a second side of the holder to seal the soil sample in the sampling barrel by having a Teflon septum positioned inside the second lid, wherein the internal taper seals the air gap between the sampling barrel and the guiding passage, the sealing of which is fu rther reinforced by the o-ring around the ejector, wherein after the second lid is detached from the sampling barrel, the first lid is detached and reversed to put the ejector in the receptive hole of the first lid so that a force can be applied on a rim of the first lid to push the ejector downwards, thereby retrieving the collected soil sample from the sampling barrel without the assistance of securing any handle to the cartridge. 8. A cartridge for extracting and preserving a soil sample, the cartridge comprising: a cylindrical sampling barrel for insertion into soil for collecting a soil sample; a guiding passage at a first end of the sampling barrel and being coaxial with the sampling barrel for hosting a rod-like ejector connected to a disk-like plunger through an internal taper, the diameter of the guiding passage being substantially smaller than that of the sampling barrel, and the rod-like ejector having an o-ring therearound to minimize the space between the ejector and the guiding passage; and a first lid securable to a first threaded connection on the cartridge, the first lid having a concentrically located nipple component with a receptive hole in the middle of the top of the nipple component with a predetermined depth, the diameter of the receptive hole being bigger than the diameter of the ejector, wherein the internal taper seals the air gap between the sampling barrel and the guiding passage while the plunger is pushed tightly toward the guiding passage, the sealing of which is further reinforced by the o-ring around the ejector, wherein, when the collected soil sample is ready to be extracted from the cartridge, the first lid is detached and reversed to put the ejector in the receptive hole so that a force can be applied on a rim of the first lid to push the ejector downwards, thereby retrieving the collected soil sample from the sampling barrel without the assistance of securing any handle to the cartridge. 9. The cartridge of claim 8 further comprising a holder on the periphery of the cartridge and close to the first threaded connection for providing a firm grip of a user when the user secures the first lid to or detaches the lid from the cartridge. 10. The cartridge of claim 8 further comprising a second lid securable to a second threaded connection for sealing the soil sample in the sampling barrel. 11. The cartridge of claim 10 wherein the second lid has a polytetrafluroethylene septum positioned inside the second lid. 12. The cartridge of claim 8 wherein the nipple component further includes a locking slot for locking a detachable handle tool onto the first lid. 13. A method for extracting a soil sample using a containment cartridge, the cartridge a cylindrical sampling barrel, a guiding passage connected at a first end of the sampling barrel and being coaxial with the sampling barrel for hosting a rod-like ejector, the ejector being connected to a disk-like plunger through an internal taper having a conical surface, and the rod-like ejector having an o-ring therearound to minimize the space between the ejector and the guiding passage, the method comprising: providing a user the cartridge with the plunger pushed tightly toward the guiding passage; securing a sampling handle tool to a first lid secured to a first threaded connection on the cartridge, the first lid having a concentrically located nipple component with a receptive hole in the middle of the top of the nipple component with a predetermined depth, the nipple component further having a locking slot for locking the handle tool onto the first lid; detaching a second lid initially secured to a second threaded connection on the cartridge to expose an opening of the sample barrel; inserting the sampling barrel into a soil sampling area by applying a force on the sampling handle tool; retrieving the sampling barrel back from the soil sampling area; sealing the soil sample in the sampling barrel by securing the second lid back ont
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