AU4242802A - Method and apparatus for injection of tubing into wells - Google Patents

Description

AUSTRALIA

Patents Act 1990 COMPLETE SPECIFICATION STANDARD PATENT Applicant(s): VITA INTERNATIONAL, INC.

Invention Title: METHOD AND APPARTUS FOR INJECTION OF TUBING INTO

WELLS

The following statement is a full description of this invention, including the best method of performing it known to me/us:

DESCRIPTION

METHOD AND APPARATUS FOR INJECTION OF TUBING INTO WELLS Technical Field The present invention relates to a coil tubing injector. More particularly, the present invention relates to a coil tubing injector with means for injecting tubing having a variable pressure means exerting pressure on the coil tubing as the tubing is injected into or removed from a well.

Background Art Continuous tubing is often used to aid in completion, servicing or production of a well.

Often, after the well has been drilled, or even during the drilling process, it is desired to pass a separate tube down the bore hole for passing gasses and fluids down into the hole for a particular purpose. For example, the tubing can be used for the circulation of nitrogen, oil, water, acid, alcohol, chemicals or solvents, for downhole workovers, location of hydrate plugs, placing of cement plugs through packers, and for circulating cement to casing bottoms, among other functions. The placement of the tube in the hole is accomplished by means of a device called an "injector", so-called because the tubing must be forced into the hole until enough of the tubing has been injected that the weight of the tubing inserted into the hole is sufficient to overcome various forces acting against movement of the tubing such as pressure in the wellbore and resistance imposed by the tubing straightener.

Normally, the tubing used is a continuous length of tubing without couplings. The use of tubing without couplings decreases the likelihood of rupture of the tubing when injecting gases and fluids into the well hole at extremely high pressures. Also, injection of continuous tubing. into the well bore at a steady rate is normally faster than assembling tubing joint by joint for lowering into the hole. Thus, continuous tubing can help save time and drilling costs.

In order to handle and store the continuous tubing, the tubing must be capable of being wound onto a reel or otherwise coiled. If the tubing material is made of PVC pipe or other high-strength plastic, coiling of the tubing for storage poses no significant problems, because the plastic tends to straighten itself when uncoiled for injection into a well bore. However, under certain downhole conditions, more durable materials are required for the tubing. For example, PVC pipe is able to withstand only relatively low pressures. Further, high-strength, low-alloy steel is often used in "sour" environments, environments in which large amounts of acid or sulfur gases are present. The use of continuous steel pipe which must be stored by coiling poses significant problems because, when uncoiled, the steel pipe tends to retain the curvature imparted to it during storage.

In some instances tubing with couplings is highly desirable. Continuous lengths of tubing can be cost prohibitive as well as presenting transport and loading problems.

Linking two sections of coiled tubing allows for longer pieces of tubing to be used in one application. Couplings may also be used to attach monitoring devices such as logging tools, gas valves, and other downhole tools. Attaching couplings allows for replacement of tubing sections that may be damaged or worn, thus extending the overall life of the tubing.

Known tubing injectors consist of a series of moving blocks driven by chains which grip the tubing on opposite sides, pulling it out of storage and injecting it into the well and straightening it at the same time. However, this type of apparatus for injecting and straightening the tubing often damages the surface of the tubing.

For example, copper tubing with fiberglass coating is used in some segments of the industry for heating thick oil in the well to facilitate production. In these situations, the fiberglass coating is easily damaged by known injecting and straightening devices.

Another limitation of known tubing injectors is the expense of maintaining them. Many of the parts wear quickly and are expensive to replace and changing the worn parts can be very difficult. A tubing injector with parts that have a longer life and are quickly and easily changed could save time and money for the operator.

By their nature coil tubing injectors have certain parts that are subjected to extreme amounts of pressure and stress. In the reel design, the tubing is held in place and straightened by exerting pressure on the tubing so that there is enough friction to hold the tubing and straighten it as it is injected into the well. Several combinations of rubber and steel surrounding the tubing have been used to achieve this result. Rubber wears out quickly and does not hold the tubing if it gets oily. Steel grooves likewise do not have enough friction to hold the tubing if they get oily and they tend to flatten the tubing if too much pressure is exerted on the tubing. Steel is also more expensive and weighs more than other polymers. A tubing injector with gripping devices that are durable yet flexible and can withstand high amounts of pressure and stress would be desirable.

Another consideration is having a tubing injector which operates independently of the equipment on the well. The recent advancement in other areas of oil and gas production in which the tubing injector is used to operate other downhole equipment or as a medium for performing various production tests and remedial operations.

When used in this manner, it is desirable that this additional equipment be placed below the injecting and straightening means.

Another problem with known tubing injectors is the resistance they provide to couplings and other attachments. If the tubing has any type of coupling device or attachment that increases the outer diameter of the tubing the injector may cause damage to the protrusion reducing the integrity of the tubing.

A durable and flexible material that can be used in place of the gripping devices described previously is polyamide. Polyamide is eighty percent lighter than steel and has a modulus of elasticity that is ninety-eight percent lower than steel. This means that the gripping device will conform to deformations caused by changes in the outer diameter of the tubing thus increasing the surface contact between the gripping device and the tubing. The surface contact is increased by almost 400% relative to steel. The increased surface contact allows for greater control over the tubing, reducing transverse movement of the tubing. These characteristics allow for longer tubing life because the tubing is less likely to be damaged by the gripping device.

Polyamide is less expensive and has a longer life than steel. Polyamide components are approximately one-third the cost of comparable steel components. Polyamide is easier and quicker to machine thus reducing labor costs. Polyamide materials are more resistant to corrosion from water and maintain a coefficient of friction of 0.03 or greater when wet.

Polyamide is superior to rubber parts used in gripping devices. Polyamide is more resistant to abrasion than rubber and does not deteriorate as quickly as rubber.

Polyanude is not effected by oil or other chemicals in an oil field. Rubber deteriorates when contacted with oil or other chemicals present in the field and the coefficient of friction is reduced when rubber is wet causing the tubing to slip. The coefficient of friction for polyamide increases when it gets wet, thus eliminating the problem of slipping present with the rubber. Polyamide also can withstand higher temperatures ,than rubber while remaining functional.

Summary of the Invention In a first aspect, the present invention provides a tubing injector including, an injecting device arranged to inject tubing into an opening, a plurality of guides mounted relative to the injecting device for guiding the tubing while being injected by the injecting device, said guides being moveable relative to the injecting device to vary compression applied to the tubing by the guides during injection of the tubing.

Preferably, the tubing injector further includes rotation means for rotating said injecting device, wherein tubing is injected into the opening on rotation of said injecting device.

In a second aspect, the present invention provides a method of changing the pressure exerted against tubing while injecting the tubing into an opening, including the steps of injecting tubing into an opening while exerting pressure against the tubing with a plurality of guides, and moving one or more of each one of said plurality of guides relative to the tubing injector to change the compression applied to the tubing during injection of the tubing.

Preferably, the present invention provides a tubing injector unit which does not damage the exterior of the coil tubing and allows couplings and other attachments to pass without being damaged.

Furthermore, the present invention preferably provides a tubing injector unit which stores the tubing evenly on a storage reel by traversing the reel as the tubing is withdrawn from the well.

In a third aspect, the present invention provides a tubing injector comprising, a base, a frame mounted to said base, an injector, device having a longitudinal axis and a perimeter, said injector device being rotatably mounted on said frame, a plurality of guide means to guide coil tubing along the perimeter of the injector device, a mounting means connecting said plurality of guide means to said injector device so that said plurality of guide means are movable radially with respect to the longitudinal axis of said injector device from a first position to a second position to vary the compression applied to the tubing during injection of the tubing, a biasing means that biases said plurality of guide means toward the first position, wherein said biasing means is connected to said mounting means, a tubing storage having coil tubing stored thereon to be fed onto the injector device, means for rotating said injector device and means for straightening said coil tubing.

Disclosure of Invention In one embodiment of the invention, there is provided a tubing injector comprising a base and an injector device mounted on the base. The injector device has a 6 longitudinal axis and a perimeter and is rotatably mounted on a frame. A plurality of guide means to guide the tubing along the perimeter of the injector device are mounted on the injector device via a mounting means so that the plurality of guide means are movable radially with respect to the longitudinal axis of the injector device from a first position to a second position. A biasing means biases the plurality of guide means toward the first position were the biasing means is connected to the mounting means.

There is a tubing storage means mounted on the base with tubing stored thereon. There is a means for rotating said injector device connected to the frame and a means for straightening the coil tubing as it is injected into or retracted from the well.

There is also provided a method for injecting and retrieving a length of tubing. The method comprises utilizing an injector device which can exert pressures of up to 5000 pounds per square inch on coil tubing. This is done by engaging a section of tubing with the injector device. The injector device has a plurality of guide means disposed thereon for guiding the tubing into the well. There is a means for receiving coil tubing on the injector device. A mounting means connects the injector device to the guide means so that the guide means is movable radially with respect to the injector device from a first position to a second position. A biasing means biases the guide means toward the first position.

The method is carried out by adjusting the biasing means to accommodate a section of tubing that has protrusions increasing the outer diameter of the tubing, while maintaining a constant force on the tubing normal to the injector device. A varying amounts of pressure are exerted on the tubing through at least one of the plurality of guide means in a controlled manner normal to the tubing to engage the tubing. The tubing is then routed by turning the injector device at the desired pressure and speed to transfer the coil tubing to the desired location. This method can be employed with all types tubing such.as copper and composite tubing that is frequently damaged by current state-of-the-art designs.

As shown in Fig. 1, one embodiment of the invention provides for a tubing injector 2 comprising a base 20 and an injector device 6 mounted on the base 20. The base can be a free standing as shown or mounted to any other stable surface such as a trailer, a truck or a platform. The injector device 6 has a longitudinal axis and a perimeter 8 and is rotatably mounted on a frame 4. A plurality of guide means 10 to guide the tubing along the perimeter 8 of the injector device 6 are mounted on the injector device 6 via a mounting means 12 so that the plurality of guide means 10 are movable radially with respect to the longitudinal axis of the injector device 6 from:a first position 14 to a second position 16. A biasing means 18 biases the plurality of guide means 10 toward the first position 14 were the biasing means 18 is connected to the mounting means 12. There is a tubing storage means 22 with coil tubing 23 stored thereon. The coil tubing 23 is fed from the tubing storage means 22 to the injector device 6. There is a means for rotating 24 said injector device 6 connected to the frame 4 and a means for straightening 26 the coil tubing as it is injected into or retracted from the well. The injector device 6 can be a reel as shown in Fig. 1 or a variety of other shapes.

In a preferred embodiment, the injector device 6, has a means for receiving coil tubing 28 forming a groove 30 positioned along the perimeter 8 of the injector device 6. The groove -30 can be U-shaped or V-shaped. The means for receiving coil tubing 28 is secured to the perimeter 8 of the injector device 6 with a pin 31 as shown in Fig. 3a.

The means for receiving coil tubing 28 is positioned along the perimeter 8 of the injector device 6 in sections, each section being held in place by pins or bolts. This construction makes replacement of the means for receiving coil tubing 28 quick and easy. The coil tubing 23 is positioned between the plurality of guide means 10 and the groove 30 when the injector device 6 is in use. Each of the plurality of guide means comprises a roller 32 having a longitudinal axis and a circumference. The circumference of the roller 32 forms a roller groove 36 for engagably receiving coil tubing 23.

The roller 32 and the means for receiving coil tubing 28 can made from the same or similar materials. Preferably, the roller 32 and means for receiving coil tubing 28 are made from a polymer compound that has the ability to withstand temperatures of 422 degrees Fahrenheit, a compressive strength of 13,920 pounds per square inch, a flexural strength of 11,000 pounds per square inch, and a flexural modulus of 350,000 pounds per square inch. The roller 32 and the means for receiving coil tubing 28 can be made from a member of the group comprising polypropylene, polyurethane, nylon, or mixtures thereof In a preferred embodiment, the roller 32 and the means for receiving coil tubing 28 are made from a member of the group comprising polyaxnide or composites of polyamide. Polyamide may be obtained from Timco of Houston, Texas. When the roller and means for receiving coil tubing are made from the compounds listed above, they are compressible up to four percent. This degree of compressibility allows for the roller and the groove to conform to tubing that has couplings or other downhole tools attached to the tubing without damaging the tubing. The roller 32 and the means for receiving coil tubing 28 preferably have a coefficient of fhction of equal to or greater than 0.03. The coefficient of friction is preferably, in the range of from about 0.03 to about 0.045. Another advantage associated with using these materials is that more fragile tubing such as composite tubing or copper tubing can be used with very little damage to the tubing. The means for receiving coil tubing 28 can also be made of steel.

In another preferred embodiment, the mounting means 12 comprises a bracket 38 detachably mounted the perimeter of the injector device 6. The bracket 3 8 is attached to the injector device 6 by at least one quick release pin 44 for holding the detachably engaging bracket 3 8 to the injector device 6 and permitting quick release and pivoting of the mounting means 12 to up to 90 degrees. This allows for easy removal of the rollers 32. The bracket 38 can be secured to the injector device 6 with a 3/4 inch bolt at a hinge point, three quick release pins for locking the guide means 10 in the closed position on the injector device 6 and one quick release pin point that enables the guide means 10 to be locked in the open position on the injector device 6. The roller 32 is capable of moving from a first position 14 to a second position 16 in response to changes in the circumference of the coil tubing 23.

Preferably, the plurality of guide means 10 are divided into groups with 4-10 guide means 10 in each group. The roller 32 has an outer diameter of 5 and 1/2 inches is capable of extending 1/4 inch to a first position 14 and retracting 3/4 inch to a second position 16. The bracket 38 has a clevis 40 mounted therein. A clevis is a generally U-shaped wire or other metal with a pin intersecting the ends of the U. The roller 32 is mounted on the bracket 38 via the clevis 40 with roller bearings 42 as shown in Fig.

4a and 4b.

Preferably, the biasing means 18 consists of an actuator means 48 for providing a controlled force normal to the coil tubing 23 and guide means 10. The coil tubing 23 is positively engaged between the groove 30 and the guide means 10 when the injector device 6 is being rotated to pull the coil tubing 23 off of the tubing storage means 22 or return the tubing to the tubing storage means 22. The actuator means 48 preferably comprises a means for remotely adjusting the pressure control adjuster which in turn adjusts the pressure exerted on the coil tubing 23. Preferably, the pressure on each roller can be adjusted individually or in groups of 4-10 rollers in each group. This allows the operator to change the pressure in response to changes in the tubing or to aid in injecting the tubing into the well.

The actuator means 48 can be a remotely operated hydraulic actuator. The hydraulic actuator preferably has 3/4 inch x 2 inch stroke single acting cylinder 50 spring return, with the cylinder 50 mounted on the top of the bracket 38 and an adaptor plug 52 disposed at the end of the shaft 54 mounted through the clevis 40 and the clevis being secured with a locking ring 56. The actuator means 48 can comprise a pressure control adjustor 64; a pressure transmitter 58 connected to the adjustor; a logic circuit 60 for directing the pressure control adjuster; and a pressure sensing means 62 connected to the logic circuit 60 so that pressure on the coil tubing 23 can be adjusted and readjusted in order to provide a constant force against the coil tubing 23 via the guide means 10. The pressure transmitter 58 can be a variable displacement pressure compensating pump, an air compressor, or an electric switching mechanism.

In another embodiment, there is provided, a method for injecting and retrieving a length of coil tubing. The method comprises utilizing an injector device 6 which can exert pressures of up to 5000 pounds per square inch on coil tubing. This is done by engaging a section of coil tubing 23 with the injector device 6. The injector device 6 has a plurality of guide means 10 disposed thereon; a means for receiving coil tubing 28; a mounting means 12 connecting the injector device 6 to the guide means 10 as described previously. The biasing means 18 is adjusted to accommodate a section of coil tubing that has protrusions increasing the outer diameter of the coil tubing, while maintaining a constant force on the coil tubing normal to the injector device 6.

Varying amounts of pressure are exerted on the coil tubing through at least one of the plurality of guide means 10 in a controlled manner normal to the coil tubing to engage the coil tubing. The coil tubing is routed by turning the injector device 6 at the desired pressure and speed to transfer the coil tubing to the desired location.

Preferably, the pressure exerted by one or more. of theplurality of guide means 10 on the coil tubing 23 can be remotely adjusted.

Preferably, the guide means 10 and the means for receiving coil tubing 28 are made from a polymer compound has the ability to withstand temperatures of 422 degrees Fahrenheit, a compressive strength of 13,920 pounds per square inch, a flexural strength of 11,000 pounds per square inch, and a flexural modulus of 350,000 pounds per square inch. The guide means 10 and the means for receiving coil tubing 28 may be made from a member of the group comprising polypropylene, polyurethane, nylon, or mixtures thereof. Further, the guide means 10 and the means for receiving coil tubing 28 can be made from a member of the group comprising polyamide or composites of polyamide. In use, polyamide allows for the guide means 10 and the means for receiving coil tubing 28 to be compressible up to four percent and have a coefficient of friction of equal to or greater than 0.03. The coefficient of friction is preferably, in the range of from about 0.03 to about 0.045. These chemical and physical properties provide superior holding capability of the injector device without damaging or flattening the coil tubing 23. Using these types of material also permits the use of coil tubing that has couplings or other downhole tools attached without damaging or flattening the injector or the coil tubing.

Although the present invention has been characterized in terms of the above-described presently preferred embodiment, it will be recognized by those skilled in the art who have the benefit of this disclosure that certain changes and variations may be made to that embodiment without departing from the spirit of the present invention. The present invention is not limited to the above-described presently preferred embodiment, and it is expected that such variations will be encompassed within the scope of the following claims.

Brief Description of Drawings Fig. 1 is a side view of the tubing injector.

Fig. 2 is an side view of the injector device.

Fig. 3 is a cross-sectional view of cut lines 3-3.

Fig. 3a is a cross-sectional view of the means for receiving coil tubing.

12 Fig. 4a is a cross-sectional view of the guide means and the mounting means where the guide means is in a first position.

Fig. 4b is a cross-sectional view of the guide means and the mounting means where the guide means is in a second position.

Fig. 5 is an end view of the injector device.

Fig. 6 is a schematic diagram of the hydraulic system of the actuator means.

Claims (61)

1. A tubing injector including: an injecting device arranged to inject tubing into an opening, a plurality of guides mounted relative to the injecting device for guiding the tubing while being injected by the injecting device, said guides being moveable relative to the injecting device to vary compression applied to the tubing by the guides during injection of the tubing.

2. A tubing injector in accordance with claim 1, further including rotation means for rotating said injecting device, wherein tubing is injected into the opening upon rotation of said injecting device.

3. A tubing injector in accordance with claim 1 or claim 2, wherein the receiving means further includes a groove, wherein the groove is arranged to engagedly receive tubing.

4. A tubing injector in accordance with claim 3, wherein the groove has a coefficient of friction of equal to or greater than 0.03. A tubing injector in accordance with claim 3 or 4, wherein each guide further includes a roller having a longitudinal axis and a circumference, wherein said circumference forms a roller groove for engagedly receiving tubing.

6. A tubing injector in accordance with claim 5, wherein said roller and said receiving means are made from a member of the chemical group comprising polyamide or composites of polyamide.

7. A tubing injector in accordance with claim 1, wherein each guide further includes a roller having a longitudinal axis and a circumference, said circumference forming a roller groove for engagedly receiving tubing, wherein saidroller and said receiving means are compressible up to four per cent. 14

8. A tubing injector in accordance with claim 5 or claim 6, wherein said roller and said receiving means are compressible up to four percent.

9. A tubing injector in accordance with claim 5, 6 or 7, wherein said roller has a coefficient of friction of equal to or greater than 0.03. A tubing injector in accordance with any one of the preceding claims, wherein said plurality of guide means are divided into groups having 4-10 guide means in each group.

11. A tubing injector in accordance with any one of the preceding claims, further including a mounting means including a bracket detachably mounted the perimeter of the forcing means.

12. A tubing injector in accordance with claim 10, wherein said bracket has a clevis mounted therein, said roller being mounted on said bracket via said clevis with roller bearings.

13. A tubing injector in accordance with claim 10, wherein said bracket is attached to said forcing means by at least one quick release pin for holding said bracket to said tubing injector and permitting quick release and pivoting of the hold down means to up to 90 degrees.

14. A tubing injector in accordance with claim 10, wherein said bracket is secured to the means with a bolt at a hinge point, three quick release pins for locking the guide means in a closed position on the forcing means and one quick release pin point that enables the guide means to be locked in an open position on the forcing means. A tubing injector in accordance with any one of the preceding claims, further including a biasing means including an actuator means for providing a controlled force normal to the tubing and guide means, wherein said tubing being positively engaged between said first groove and said guide means when said forcing means is being 15 rotated to pull said tubing off of said tubing storage means or return said tubing to said tubing storage means.

16. A tubing injector in accordance with claim 14, wherein said actuator means includes a pressure control adjustor, a pressure transmitter connected to said adjustor; a logic circuit for directing the pressure control adjuster; and a pressure sensing means connected to the logic circuit so that pressure on the coil tubing can be adjusted and readjusted in order to provide a constant force against the coil tubing via the guide means.

17. A tubing injector in accordance with claim 15, wherein the actuator is a hydraulic actuator.

18. A tubing injector in accordance with claim 16, wherein the hydraulic actuator further includes a single acting cylinder spring return, with said cylinder spring return mounted on the top of the bracket and an adaptor plug disposed at the end of a shaft mounted through the clevis and the clevis being secured with a locking ring.

19. The tubing injector in accordance with claim 15, wherein said actuator means 2 0 further includes a means for remotely adjusting the pressure exerted on the coil tubing. A method of changing the pressure exerted against tubing while injecting the tubing into an opening, including the steps of injecting tubing into an opening while exerting pressure against the tubing with a plurality of guides; and moving one or more of each one of said plurality of guides relative to the tubing injector to vary the compression applied to the tubing during injecting of the tubing.

21. A method in accordance with claim 19, further including, remotely adjusting the 3 0 pressure exerted on one or more of the plurality of guide means. 16

22. A method in accordance with claim 19, wherein the step of exerting pressure against the tubing with a plurality of guides further includes a means for receiving coil tubing being made from a polymer compound.

23. A method in accordance with claim 21, wherein the polymer compound has the ability to withstand temperatures of 422 degrees Fahrenheit, a compressive strength of 13,920 pounds per square inch, a flexural strength of 11,000 pounds per square inch, and a flexural modulus of 350,000 pounds per square inch.

24. A method in accordance with claim 21, wherein the polymer compound is made from a member of the group comprising polypropylene, polyurethane, nylon, or mixtures thereof. The method of claim 21, wherein the polymer compound is made from a member of the group comprising polyamide or composites of polyamide.

26. The method of claim 19, wherein the step of exerting pressure against the tubing includes compressing at least one of said plurality of guides and said means for receiving coil tubing up to four percent.

27. The method of claim 19, wherein the step of engaging a section of tubing includes providing a guide means and a means for receiving coil tubing having a coefficient of friction of equal to or greater than 0.03.

28. A tubing injector in accordance with any one of the preceding claims, wherein the receiving means is made from steel.

29. A tubing injector comprising: a base; a frame mounted to said base; an injector device having a longitudinal axis and a perimeter, said injector device being rotatably mounted on said frame; a plurality of guide means to guide coil tubing along the perimeter of 17 the injector device; a mounting means connecting said plurality of guide means to said injector device so that said plurality of guide means are movable radially with respect to the longitudinal axis of said injector device from a first position to a second position to vary the compression applied to the tubing during injection of the tubing; a biasing means that biases said plurality of guide means toward the first position, wherein said biasing means is connected to said mounting means; a tubing storage having coil tubing stored thereon to be fed onto the injector device; means for rotating said injector device; and means for straightening said coil tubing. A tubing injector in accordance with claim 29, wherein the injector device further includes a means for receiving tubing, the receiving means further including a groove, wherein the groove is arranged to engagedly receive tubing.

31. A tubing injector in accordance with claim 30, wherein the groove has a coefficient of friction of equal to or greater than 0.03.

32. A tubing injector in accordance with claim 29 or 30, wherein each guide further includes a roller having a longitudinal axis and a circumference, wherein said circumference forms a roller groove for engagedly receiving tubing.

33. A tubing injector in accordance with claim 32, wherein said roller and said receiving means are made from a member of the chemical group comprising polyamide or composites of polyamide.

34. A tubing injector in accordance with claim 29, wherein each guide further includes a roller having a longitudinal axis and a circumference, said circumference forming a roller groove for engagedly receiving tubing, wherein said roller and said receiving means are compressible up to four per cent. 18 A tubing injector in accordance with claim 33 or claim 34, wherein said roller and said receiving means are compressible up to four percent.

36. A tubing injector in accordance with claim 33, 34 or 35, wherein said roller has a coefficient of friction of equal to or greater than 0.03.

37. A tubing injector in accordance with any one of the preceding claims, wherein said plurality of guide means are divided into groups having 4-10 guide means in each group.

38. A tubing injector in accordance with any one of the preceding claims, further including a mounting means including a bracket detachably mounted the perimeter of the forcing means.

39. A tubing injector in accordance with claim 38, wherein said bracket has a clevis mounted therein, said roller being mounted on said bracket via said clevis with roller bearings. A tubing injector in accordance with claim 38, wherein said bracket is attached to said forcing means by at least one quick release pin for holding said bracket to said tubing injector and permitting quick release and pivoting of the hold down means to up to 90 degrees.

41. A tubing injector in accordance with claim 38, wherein said bracket is secured to the means with a bolt at a hinge point, three quick release pins for locking the guide means in a closed position on the forcing means and one quick release pin point that enables the guide means to be locked in an open position on the forcing means.

42. A tubing injector in accordance With any one of the preceding claims, further including a biasing means including an actuator means for providing a controlled force normal to the tubing and guide means, wherein said tubing being positively engaged between said first groove and said guide means when said forcing means is being 19 rotated to pull said tubing off of said tubing storage means or return said tubing to said tubing storage means.

43. A tubing injector in accordance with claim 42, wherein said actuator means includes a pressure control adjustor, a pressure transmitter connected to said adjustor; a logic circuit for directing the pressure control adjuster; and a pressure sensing means connected to the logic circuit so that pressure on the coil tubing can be adjusted and readjusted in order to provide a constant force against the coil tubing via the guide means.

44. A tubing injector in accordance with claim 43, wherein the actuator is a hydraulic actuator. A tubing injector in accordance with claim 44, wherein the hydraulic actuator further includes a single acting cylinder spring return, with said cylinder spring return mounted on the top of the bracket and an adaptor plug disposed at the end of a shaft mounted through the clevis and the clevis being secured with a locking ring.

46. The tubing injector in accordance with claim 43, wherein said actuator means further includes a means for remotely adjusting the pressure exerted on the coil tubing.

47. A tubing injector comprising: a base; a frame mounted to said base; an injector device having a longitudinal axis and a perimeter, said injector device being rotatably mounted on said frame; a plurality of guide means to guide coil tubing along the perimeter of the injector device; a mounting means connecting said plurality of guide means to said injector device so that said plurality of guide means are movable radially with respect to the longitudinal axis of said injector device from a first position to a second position; a biasing means that biases said plurality of guide means toward the first position, wherein said biasing means is connected to said mounting means; 20 a tubing storage having coil tubing stored thereon to be fed onto the injector device; means for rotating said injector device; and means for straightening said coil tubing.

48. A tubing injector as in claim 47, wherein the injector device further comprises a means for receiving coil tubing forming a groove positioned along the perimeter of the injector device so that the coil tubing is positioned between said plurality of guide means and said groove, said groove having a coefficient of friction of equal to or greater than 0.03.

49. A tubing injector as in claim 47, wherein each of said plurality of guide means comprises a roller having a longitudinal axis and a circumference, wherein said circumference forms a groove for engagably receiving tubing. A tubing injector as in claim 49, wherein said roller and said means for receiving coil tubing are made from a polymer compound having the ability to withstand temperatures of 422 degrees Fahrenheit, a compressive strength of 13,920 pounds per square inch, a flexural strength of 11,000 pounds per square inch, and a flexural modulus of 350,000 pounds per square inch.

51. A tubing injector as in claim 49, wherein the roller and said means for receiving coil tubing are made from a member of the group comprising polypropylene, polyurethane, nylon, or mixtures thereof.

52. A tubing injector as in claim 49, wherein said roller and said means for receiving coil tubing are made from a member of the group comprising polyamide or composites of polyamide.

53. A tubing injector as in claim 49, wherein said roller and said means for receiving coil tubing are compressible up to four percent. 21 53. A tubing injector as in claim 49, wherein said roller having an outer diameter of and 1/2 inches is capable of extending 1/4 inch and retracting 3/4 inch.

54. A tubing injector as in claim 49, wherein said roller and said means for receiving coil tubing have a coefficient of friction of equal to or greater than 0.03. A tubing injector as in claim 47, wherein said plurality of guide means are divided into groups having 4-10 guide means in each group.

56. A tubing injector as in claim 47, wherein the mounting means comprises a bracket detachably mounted the perimeter of the injector device.

57. A tubing injector as in claim 55, wherein said bracket has a clevis mounted therein, said roller being mounted on said bracket via said clevis with roller bearings.

58. A tubing injector as in claim 55, wherein said bracket is attached to said injector device by at least one quick release pin for holding said detachably engaging bracket to said injector device and permitting quick release and pivoting of the hold down means to up to 90 degrees.

59. A tubing injector as in claim 55, wherein said bracket is secured to the injector device with a 3/4 inch bolt at a hinge point, three quick release pins for locking the guide means in the closed position on the injector device and one quick release pin point that enables the guide means to be locked in the open position on the injector device. A tubing injector as in claim 48, wherein said biasing means consists of an actuator means for providing a controlled force normal to the tubing and guide means, wherein said tubing being positively engaged between said groove and said guide means when said injector device is being rotated to pull said tubing off of said tubing storage means or return said tubing to said tubing storage means. 22

61. A tubing injector as in claim 60, wherein said actuator means comprises a pressure control adjustor, a pressure transmitter connected to said adjustor; a logic circuit for directing the pressure control adjuster; and a pressure sensing means connected to the logic circuit so that pressure on the coil tubing can be adjusted and readjusted in order to provide a constant force against the coil tubing via the guide means.

62. A tubing injector as in claim 60, wherein said roller is moved from a first position to a second position in response to changes in the circumference of the tubing.

63. A tubing injector as in claim 61, wherein the actuator is a hydraulic actuator.

64. The hydraulic actuator of claim 63 having a 3/4 inch x 2 inch stroke single acting cylinder spring return, with said cylinder mounted on the top of the bracket and an adaptor plug disposed at the end of the shaft mounted through the clevis and the clevis being secured with a locking ring. The tubing injector of claim 61, wherein said actuator means further comprises a means for remotely adjusting the pressure exerted on the coil tubing.

66. A method for injecting and retrieving a length of tubing comprising: e utilizing an injector device which can exert pressures of up to 5000 pounds per square inch on coil tubing by: engaging a section of tubing with the injector device, wherein the injector device has a plurality of guide means disposed thereon; a means for receiving coil tubing; a mounting means connecting the injector device to the guide means so that the guide means is movable radially with respect to the injector device from a first position to a second position; and a-biasing means that biases the guide means toward the first position; adjusting the biasing means to accommodate a section of tubing having protrusions that increase the outer diameter of the tubing, while maintaining a constant force on the tubing normal to the injector device; exerting varying amounts of pressure on said tubing through at least one of the 23 plurality of guide means in a controlled manner normal to the tubing to engage the tubing; routing the tubing by turning the injector device at the desired pressure and speed to transfer the coil tubing to the desired location.

67. The method of claim 66, further comprising, remotely adjusting the pressure exerted on one or more of the plurality of guide means.

68. The method of claim 66, wherein the step of engaging a section of tubing includes providing a guide means and a means for receiving coil tubing being made from a polymer compound having the ability to withstand temperatures of 422 degrees Fahrenheit, a compressive strength of 13,920 pounds per square inch, a flexural strength of 11,000 pounds per square inch, and a flexural modulus of 350,000 pounds per square inch.

69. The method of claim 66,wherein the step of engaging a section of tubing includes providing a guide means and a means for receiving coil tubing being made from a member of the group comprising polypropylene, polyurethane, nylon, or mixtures thereof. ,70. The method of claim 66,wherein the step of engaging, a section of tubing includes providing a guide means and a means for receiving coil tubing being made from a member of the group comprising polyamide or composites of polyamide.

71. The method of claim 66, wherein the step of engaging a section of tubing includes compressing said guide means and said means for receiving coil tubing up to four percent.

72. The method of claim 66,wherein the step of engaging a section of tubing includes providing a guide means having an outer diameter of 5 and 1/2 inches being capable of extending 1/4 inch and retracting 3/4 inch. 24

73. The method of claim 66,wherein the step of engaging a section of tubing includes providing a guide means and a means for receiving coil tubing having a coefficient of friction of equal to or greater than 0.03.

74. A tubing injector as in claim 49, wherein said means for receiving coil tubing is made from steel. A tubing injector as substantially described herein, with reference to the accompanying drawings.

76. A method of injecting tubing as substantially described herein, with reference to the accompanying drawings. Dated this 22nd day of May 2002 VITA INTERNATIONAL, INC. By their Patent Attorneys GRIFFITH HACK