diy well drilling mud pump quotation

Explore the various water well drills with mud pump products available for wholesale at Alibaba.com. Get a water well drills with mud pump for drilling water wells, water exploration holes, geological exploration, coal mines, and other kinds of mining. Some water well drills with mud pump options use caterpillar tread to move. Others use rubber tires, while others require a separate means of transport. Caterpillar tread propulsion can climb up to 25 degrees inclination. Some products in the range are capable of drilling over 200 meters, while others are only used for open-pit mining with depths of around 3 meters. Drilling can be done vertically downwards, horizontally, or in a slanting direction. Drilling speed depends on the power of the machine and the general hardness of the surface. The hole diameter can vary from 90mm to 200mm.

water well drills with mud pump options also include an air compressor, a mud pump, drilling rods of various sizes, connectors, and a drilling tower. Drilling is done using drill bits of various shapes, sizes, and compositions. You can choose between diamond bits, alloy ring-shaped bits, 3-wing alloy bits, PDC bits, and hammer bits. Each drill bit uses different drilling methods, including rotary, percussion, blast hole, and core drilling.

Smaller products have a lifting power of around 25 kilonewtons and weigh about 2,500kgs. They’re ideal for small-scale drillings such as farms and homes. Larger ones are faster with more power, making them ideal for commercial use. Browse through Alibaba.com and find a water well drills with mud pump that’s ideal for your work scope. Buy mine drilling rigs for your wholesale business at competitive prices. Chinese wholesalers provide you with customization options and great after-sales services.

Mud pumps, or mud drilling rigs, are also used as water well drilling rigs, to address water concerns at the bottom of the mines. Mud pumps, also known as mud drilling rigs, are water well drilling rigs that are used to extract water from pits, and mud drilling rigs. The mud water drilling rig is also called as water well drilling rigs, and are also called as water well drilling rigs. The mud pumps, mud drilling rigs, are also called as water well drilling rigs, for example, droplets or mud pumps. They are designed to cut slurry from pits, mud pits, and mud drilling rigs. The most common mud pumps and mud drilling rigs are also called as water well drilling rigs, to mud pits.@@@@@

A water well drilling rig can consist of a large amount of mud, which is easily drained by due to the conditions of the water being high. There is also a band of mud trucks and drilling holes that are adequate for flowing water.@@@@@

A gasoline powered pump, also known as an off-road mud drilling rig, is a good choice for people that choose either a gasoline-powered pump or a water well driller rig. Gasoline-powered water well driller rig, for example, is a type of water well drilling rig that has two or more volt engines. On the other hand, a gasoline-powered water well driller rig is hard to distinguish from one of these two. Generally speaking, a gasoline-powered water well driller rig is one with the energy of a day, it is important to consider the type of water well drilling rig that is powered by a gasoline-powered pump, for instance, is a by-product of the two types of water well drilling rig. For instance, a gasoline-powered water well driller rig is by one that is high-pressure, and a two-stroke engine.@@@@@

Choosing the mud pumps depends on the size, the course of time, and the surface of the water. For instance, a one-stroke mud pumps depends on the size and the type of mud pumps. For instance, gasoline-powered is an electric version of the water well drilling rig.

OK, all y’all air drillers just thumb on over to Porky’s column or something. This is for mud drillers. On second thought, I know a lot of you air guys drill about three mud wells a year, and consider it a hassle to rig up mud. So, maybe something I say will be interesting …

The mud pump is the heart of the circulating system, and mud is the blood circulating in the hole. I’ve talked about mud before and will again, but this month, let’s talk about the pump.

Historically, more wells, of every kind, have been drilled with duplex pumps than any other kind. They are simple and strong, and were designed in the days when things were meant to last. Most water well drillers use them. The drawbacks are size and weight. A pump big enough to do the job might be too big to fit on the rig, so some guys use skid-mounted pumps. They also take a fair amount of horsepower. If you were to break down the horsepower requirements of your rig, you would find out that the pump takes more power than the rotary and hoist combined. This is not a bad thing, since it does a lot of the work drilling. While duplex pumps generally make plenty of volume, one of the limiting factors is pressure. Handling the high pressures demanded by today’s oil well drilling required a pump so big and heavy as to be impractical. Some pretty smart guys came up with the triplex pump. It will pump the same — or more — volume in a smaller package, is easy to work on and will make insane pressure when needed. Some of the modern frack outfits run pumps that will pump all day long at 15,000 psi. Scary. Talk about burning some diesel.

The places that triplex pumps have in the shallow drilling market are in coring and air drilling. The volume needs are not as great. For instance, in hard rock coring, surface returns are not always even seen, and the fluid just keeps the diamonds cool. In air drilling, a small triplex is used to inject foam or other chemicals into the air line. It’s basically a glorified car wash pump. The generic name is Bean pump, but I think this just justifies a higher price. Kinda like getting the same burger at McDonald’s versus in a casino.

One of the reasons water well drillers don’t run triplex pumps, besides not needing insane pressure, is they require a positive suction head. In other words, they will not pick up out of the pit like a duplex. They require a centrifugal charging pump to feed them, and that is just another piece of equipment to haul and maintain.

This brings me to another thought: charging. I know a lot of drillers running duplex pumps that want to improve the efficiency of their pumps. Duplexes with a negative suction head generally run at about 85 percent efficiency. The easy way to improve the efficiency is to charge them, thus assuring a 100 percent efficiency. This works great, but almost every one of them, after doing all that work and rigging up a charging pump, tells me that their pump output doubled. Being the quiet, mild mannered type that I am, I don’t say “Bull,” but it is. A duplex pump is a positive displacement pump. That means that it can deliver no more than the displacement it was designed for. You can only fill the cylinder up until it is full. It won’t take any more. The one exception to this is when you are pumping at very low pressure. Then the charging pump will over run the duplex, float the valves and produce a lot more fluid. Might as well shut off the duplex and drill with the charging pump.

Another common pump used in the water well industry is the centrifugal. You see them mostly on air rigs that don’t use mud too often. They have their place, but are a different breed of cat. They are not positive displacement. Flow is a function of speed and horsepower up to the limits of the pump. After that, they just dead-head. With large diameter drill pipe they make a lot of mud, but after the hole gets deeper, friction losses — both inside and outside the drill pipe — build up. This means that the deeper you go, the less circulation you have. This slows the whole process. Positive displacement pumps don’t do this; they pump the same per stroke regardless of pressure. It just takes more horsepower. Also, displacement calculations like bottoms-up time and cement placement are just about impossible. One way to get around the limited pressure of centrifugal pumps is to run two of them in series. I’ve seen a few of these rig-ups and they work very well for large diameter drilling. They will make almost the same pressure as a big duplex for a lot less money. They are still variable displacement, but they roll so much fluid that it doesn’t seem to matter. And run at pretty reasonable depths, too: 300 to 400 psi at 400 gpm is not uncommon with two 3 x 4 centrifugal pumps in series.

I reckon there are pumps for every type of drilling. It is just a matter of using the right one correctly. I once drilled a 42-inch hole 842 feet deep with a 5½ x 8 duplex. Talk about long bottoms-up time … but we got the casing in with less than two feet of fill on bottom! Took time, but we got-er-done.

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Greetings Tim & Charlott, below is a GPS link and information on the well we just installed in the honor of Tim & Charlott King! Your love and commitment has allowed our Clean Water 4 Life ministry to sink over 500 water wells for those in need here in the Solomon Islands! Here is a link to read my current newsletter with lots of pictures! http://www.rickrupp.com/newsletter.php

Togokoba SSEC Church & Community is approx 58 kilometers east of Honiara. It was a long bumpy drive to this village. I had to walk a long way to get to the place where they lived. They explained that their source of drinking water was the stream. They were so happy when I explained that our CW4L team was going to come sink a well right in their village. I tasted the well water several weeks later after our team had blessed them with a water well. It tasted so good! It was nice clean & cold water! It never ceases to amaze me that there is such a nice water table here in the rural areas of the Guadnacanal plains! I counted 10 houses in this community and the population is approx 80 people. Now they finally have a source of clean drinking water! These people have suffered for many years either drinking from an open hand dug well or from the stream. Togokoba SSEC Church & Community is very grateful to our CW4L sponsors.

The drilling industry has roots dating back to the Han Dynasty in China. Improvements in rig power and equipment design have allowed for many advances in the way crude oil and natural gas are extracted from the ground. Diesel/electric oil drilling rigs can now drill wells more than 4 miles in depth. Drilling fluid, also called drilling mud, is used to help transfer the dirt or drill cuttings from the action of the drilling bit back to the surface for disposal. Drill cuttings can vary in shape and size depending on the formation or design of the drill bit used in the process.

Watch the video below to see how the EDDY Pump outperforms traditional pumps when it comes to high solids and high viscosity materials commonly found on oil rigs.

Solids control equipment including shakers, hydro-cyclones, and centrifuges are utilized to clean the drill cuttings from the drilling fluid, which then allows it to be reused and recirculated. The circuit includes the mixing of the drilling fluid in the rig tanks.

The drilling fluid is prepared to control fluid loss to the formation by the addition of chemicals or mineral agents. Commercial barite or other weighting agents are added to control the hydrostatic pressure exuded on the bottom of the well which controls formation pressures preventing fluid or gas intrusion into the wellbore.

The fluid is charged into high-pressure mud pumps which pump the drilling mud down the drill string and out through the bit nozzles cleaning the hole and lubricating the drill bit so the bit can cut efficiently through the formation. The bit is cooled by the fluid and moves up the space between the pipe and the hole which is called the annulus. The fluid imparts a thin, tough layer on the inside of the hole to protect against fluid loss which can cause differential sticking.

The fluid rises through the blowout preventers and down the flowline to the shale shakers. Shale shakers are equipped with fine screens that separate drill cutting particles as fine as 50-74 microns. Table salt is around 100 microns, so these are fine cuttings that are deposited into the half-round or cuttings catch tank. The drilling fluid is further cleaned with the hydro-cyclones and centrifuges and is pumped back to the mixing area of the mud tanks where the process repeats.

The drill cuttings contain a layer of drilling fluid on the surface of the cuttings. As the size of the drill cuttings gets smaller the surface area expands exponentially which can cause rheological property problems with the fluid. The fluid will dehydrate and may become too thick or viscous to pump so solids control and dilution are important to the entire drilling process.

One of the most expensive and troubling issues with drilling operations is the handling, processing, and circulation of drilling mud along with disposing of the unwanted drill cuttings. The drilling cuttings deposited in the half round tank and are typically removed with an excavator that must move the contents of the waste bin or roll-off box. The excavators are usually rented for this duty and the equipment charges can range from $200-300/day. Add in the cost for the day and night manpower and the real cost for a single excavator can be as much as $1800/day.

Offshore drilling rigs follow a similar process in which the mud is loaded into empty drums and held on the oil platform. When a certain number of filled drums is met, the drums are then loaded onto barges or vessels which take the drilling mud to the shore to unload and dispose of.

Oil field drilling operations produce a tremendous volume of drill cuttings that need both removal and management. In most cases, the site managers also need to separate the cuttings from the drilling fluids so they can reuse the fluids. Storing the cuttings provides a free source of stable fill material for finished wells, while other companies choose to send them off to specialty landfills. Regardless of the final destination or use for the cuttings, drilling and dredging operations must have the right high solids slurry pumps to move them for transport, storage, or on-site processing. Exploring the differences in the various drilling fluids, cutting complications, and processing options will reveal why the EDDY Pump is the best fit for the job.

The Eddy Pump is designed to move slurry with solid content as high as 70-80 % depending on the material. This is an ideal application for pumping drill cuttings. Drill cuttings from the primary shakers are typically 50% solids and 50% liquids. The Eddy Pump moves these fluids efficiently and because of the large volute chamber and the design of the geometric rotor, there is very little wear on the pump, ensuring long life and greatly reduced maintenance cost for the lifetime of the pump.

plumbed to sweep the bottom of the collection tank and the pump is recessed into a sump allowing for a relatively clean tank when the solids are removed. The Eddy Pump is sized to load a roll-off box in 10-12 minutes. The benefit is cuttings handling is quicker, easier, safer, and allows for pre-planning loading where the labor of the solids control technician is not monopolized by loading cuttings. Here, in the below image, we’re loading 4 waste roll-off bins which will allow the safe removal of cuttings without fear of the half-round catch tank running over.

Mud cleaning systems such as mud shaker pumps and bentonite slurry pumps move the material over screens and through dryers and centrifuges to retrieve even the finest bits of stone and silt. However, the pump operators must still get the raw slurry to the drill cuttings treatment area with a power main pump. Slurry pumps designed around the power of an Eddy current offer the best performance for transferring cuttings throughout a treatment system.

Options vary depending on whether the company plans to handle drill cuttings treatment on-site or transport the materials to a remote landfill or processing facility. If the plan is to deposit the cuttings in a landfill or a long-term storage container, it’s best to invest in a pump capable of depositing the material directly into transport vehicles. Most dredging operations rely on multiple expensive vacuum trucks, secondary pumps, and extra pieces of equipment.

Using an EDDY Pump will allow a project to eliminate the need for excavators/operators to load drill cuttings, substantially lowering both labor and heavy equipment costs. The EDDY Pump also allows a company to eliminate vacuum trucks once used for cleaning the mud system for displacing fluids. Since the pump transfers muds of all types at constant pressure and velocity throughout a system of practically any size, there’s little need for extra equipment for manual transfer or clean up on the dredge site.

The EDDY Pump can fill up a truck in only 10 minutes (compared to an hour) by using a mechanical means such as an excavator. For this reason, most companies can afford one piece of equipment that can replace half a dozen other units.

This application for the Eddy Pump has the potential to revolutionize the drilling industry. Moving the excavator out of the “back yard” (the area behind the rig from the living quarters) will make cuttings handling a breeze. Trucking can be easier scheduled during daylight hours saving on overtime and incidences of fatigued driving. Rig-site forklifts can move the roll-off boxes out of the staging area and into the pump loading area. The operator can save money on excavators rental, damages, and keep the technician operating the solids control equipment.

The EDDY Pump is ideal for drilling mud pump applications and can be connected directly onto the drilling rigs to pump the drilling mud at distances over a mile for disposal. This eliminates the need for costly vacuum trucks and also the manpower needed to mechanically move the drilling mud. The reasons why the EDDY Pump is capable of moving the drilling mud is due to the hydrodynamic principle that the pump creates, which is similar to the EDDY current of a tornado. This tornado motion allows for the higher viscosity and specific gravity pumping ability. This along with the large tolerance between the volute and the rotor allows for large objects like rock cuttings to pass through the pump without obstruction. The large tolerance of the EDDY Pump also enables the pump to last many times longer than centrifugal pumps without the need for extended downtime or replacement parts. The EDDY Pump is the lowest total life cycle pump on the market.

from http:www.drillyourownwell.com George of Fayetteville NC sent us this video which demonstrates the phenomenal success his crew had in drilling a well with a mud pump! From the Drill Your Own Well series

Here is a first rendering of the well drilling rig as rendered in BRL-CAD. The hydraulic pump (green) from the MicroTrac is shown mounted with the shaft downwards on the blue sliding frame which moves up and down the side tracks. The mounting of the motor to the green frame will use the same two bolt quick release system employed by the MicroTrac to allow for interoperability and quick changeovers from one device to the other. The rotating shaft from the hydraulic pump is connected to the purple section of drill string piping which stays centered in the swivel tee allowing drilling mud to flow into it and down the drill string (shown in light green). The purple section of piping is held horizontally by the holes in the top and bottom of the frame which are only slightly bigger than the purple pipe. This purple section of piping is supported vertically by the rotating bearing assembly which rides on the top of the sliding frame. If rock is encountered while drilling the small circular plate above the bearing will push the bearing down putting extra weight on the drill string. This allows weights to be hung along the back panel of the frame allowing the amount of downward force on the drill string to be manipulated. In the reverse situation, when tripping the drill string out of the hole, the purple section will pull down on the bearing causing it to move off the circular plate and against the frame below, pushing down on the frame and holding up the drill string as it is withdrawn from the well.

At ground level the the drill string passes through the red drill collar which bolts down to the gray baseplate allowing it to be easily removed or swapped for a smaller diameter collar (the square collar flange plate will be the same for all collars allowing for interchangeability). The machine currently is shown with a 6 inch inside diameter collar allowing a 6 inch well casing ti exactly fit inside it. At the bottom of the drill string a simple gray bit is shown which is just a section of 6" pipe with partially covered end caps connected to the bottom of the lowest section of drill string piping. Since the actual drill string piping is much smaller than 6 inches (probably only 3 or 4 inches at most for a water well drilling rig) the collar can also serve analogous to the function of a rotary table on an oil rig allowing a slip to be used to support the drill string when it is detached from the turning head at the top of the rig.

The vertical side tracks can either be composed of three flat pieces of steel welded along the edges to form a channel or can be made from large (~10 cm or bigger square tubing which has been cut in half lengthwise). If additional ground stability on the baseplate is required, four long steel stakes can be driven through the corners of the baseplate to prevent it from sliding. If these stakes are just simple pieces of re-bar they can even be left in place after the baseplate is removed (when the drilling rig is lifted straight up, or tipped down to one side the baseplate would just lift off the top of the stakes), these could then be cemented into the top pad when the wellhead is capped preventing it from sliding off the top of the well, or they can be removed for re-use as well.

The side tracks bolt to the baseplate and to each other with additional plates on the outside of the tracks a pair of bolts at each end (outer plates not shown). Since the bolt holes on all pieces of this side track material are 10 cm and 20 cm in from the ends of the piece they are interchangeable with or attachable to any other piece no matter whether they bolt to the baseplate, the top crown, or another section. This interchangeability on the side rails means you can build a small test rig with short rails for prototyping and shallow well drilling and then later on you can add additional height to the drill rig by adding on longer tracks letting you run deeper before having to break the drill string to add another section (making digging very deep wells much faster). Disassembling the side tracks would be easy to do (only 4 bolts per section) allowing the tracks to be disassembled for long distance transport and the re-assembled at the well site. In order to make room for the bolt heads on the inside of the tracks, the blue frame has 4 cm by 4 cm channels cut into each side; this lets the bolts securing the side tracks pass by without affecting the guiding done by the outside corners of the frame.

For short distance transport the rig can be tipped down and pulled on the wheels (a hitch could be attached at the top of the crown). When the rig is at the well site it is tipped up (which should be possible for 2 people to do) and it is held upright by the red arm on the top which will attach to a specially designed ground stake. The red support rod also prevents torsion of the top of the machine due to the length of the crossmember. The support rod can be used either in front of, or behind the drilling rig depending on the layout of the site and the ground conditions. A second mode of transport can be achieved if you want to drill many wells in a small area, for example along the edge of a field. When the rig is upright the wheels can be easily removed by removing the pins holding in the red wheel supports. Once the wheels are off the rig can be picked up by the tractor using the small red lifting brackets seen on the rails behind the sliding frame. These brackets should fit perfectly on the mounting for the tractor, it would be like picking up the bucket or any of the other front end tools. This allows the rig to be easily repositioned since the tractor can just set it down right on the wellhead. After it is set in place the red rod is secured on the front side of the rig. The tractor can then detach from the drill rig and use the bail spike to raise and lower the sliding frame (instead of using the manual winch which some builders of the rig may choose to omit entirely).

Please let me know what you think about the pictured design, once I have added the rest of the drilling equipment and after making any changes suggested here, I will post the .g file so other people can play around with it.

After the well is finished the walls of the well need to be prevented from caving in and collapsing the well, this is the job of well casing. Well casing is usually installed after the well is drilled out (i.e. casing is not present during the drilling operations), however in very soft soil the well may need to be cased even during the drilling phase. If this is required you can drill for some distance with the largest bit you have, then case that section, then use a smaller bit to drill further, case that section with smaller well casing, etc. The well casing for most of the well can be simple pipe, approximately 4 to 6 inches in diameter for a typical well; the bottom section should have holes drilled in it and/or sections of screen to allow the water to infiltrate into the well bore from the aquifer.

You need a minimum of 4"/100mm to allow for installation of cast iron cylinder for India MKII or MKIII by AOV. This will also allow installation of the Afri-Dev type pump.

Normal heat pumpheating for typical house needs 200m deep hole or two. Typical sale price for one hole is near 5000eur per customer. (60N, granite bed rock). Hole field is also great way to store summer solar heat and use it winter. Only problem is current price for hole fields .

There are many different ways to drill a domestic water well. One is what we call the “mud rotary” method. Whether or not this is the desired and/or best method for drilling your well is something more fully explained in this brief summary.

One advantage of drilling with compressed air is that it can tell you when you have encountered groundwater and gives you an indication how much water the borehole is producing. When drilling with water using the mud rotary method, the driller must rely on his interpretation of the borehole cuttings and any changes he can observe in the recirculating fluid. Mud rotary drillers can also use borehole geophysical tools to interpret which zones might be productive enough for your water well.

The mud rotary well drilling method is considered a closed-loop system. That is, the mud is cleaned of its cuttings and then is recirculated back down the borehole. Referring to this drilling method as “mud” is a misnomer, but it is one that has stuck with the industry for many years and most people understand what the term actually means.

The water is carefully mixed with a product that should not be called mud because it is a highly refined and formulated clay product—bentonite. It is added, mixed, and carefully monitored throughout the well drilling process.

The purpose of using a bentonite additive to the water is to form a thin film on the walls of the borehole to seal it and prevent water losses while drilling. This film also helps support the borehole wall from sluffing or caving in because of the hydraulic pressure of the bentonite mixture pressing against it. The objective of the fluid mixture is to carry cuttings from the bottom of the borehole up to the surface, where they drop out or are filtered out of the fluid, so it can be pumped back down the borehole again.

When using the mud rotary method, the driller must have a sump, a tank, or a small pond to hold a few thousand gallons of recirculating fluid. If they can’t dig sumps or small ponds, they must have a mud processing piece of equipment that mechanically screens and removes the sands and gravels from the mixture. This device is called a “shale shaker.”

The driller does not want to pump fine sand through the pump and back down the borehole. To avoid that, the shale shaker uses vibrating screens of various sizes and desanding cones to drop the sand out of the fluid as it flows through the shaker—so that the fluid can be used again.

When the borehole has reached the desired depth and there is evidence that the formation it has penetrated will yield enough water, then it’s time to make the borehole into a well.

Before the well casing and screens are lowered into the borehole, the recirculating fluid is slowly thinned out by adding fresh water as the fluid no longer needs to support sand and gravel. The driller will typically circulate the drilling from the bottom up the borehole while adding clear water to thin down the viscosity or thickness of the fluid. Once the fluid is sufficiently thinned, the casing and screens are installed and the annular space is gravel packed.

Gravel pack installed between the borehole walls and the outside of the well casing acts like a filter to keep sand out and maintain the borehole walls over time. During gravel packing of the well, the thin layer of bentonite clay that kept the borehole wall from leaking drilling fluid water out of the recirculating system now keeps the formation water from entering the well.

This is where well development is performed to remove the thin bentonite layer or “wall cake” that was left behind. Various methods are used to remove the wall cake and develop the well to its maximum productivity.

Some drillers use compressed air to blow off the well, starting at the first screened interval and slowly working their way to the bottom—blowing off all the water standing above the drill pipe and allowing it to recover, and repeating this until the water blown from the well is free of sand and relatively clean. If after repeated cycles of airlift pumping and recovery the driller cannot find any sand in the water, it is time to install a well development pump.

Additional development of the well can be done with a development pump that may be of a higher capacity than what the final installation pump will be. Just as with cycles of airlift pumping of the well, the development pump will be cycled at different flow rates until the maximum capacity of the well can be determined. If the development pump can be operated briefly at a flow rate 50% greater than the permanent pump, the well should not pump sand.

Mud rotary well drillers for decades have found ways to make this particular system work to drill and construct domestic water wells. In some areas, it’s the ideal method to use because of the geologic formations there, while other areas of the country favor air rotary methods.

Some drilling rigs are equipped to drill using either method, so the contractor must make the decision as to which method works best in your area, for your well, and at your point in time.

To learn more about the difference between mud rotary drilling and air rotary drilling, click the video below. The video is part of our “NGWA: Industry Connected” YouTube series:

Gary Hix is a Registered Professional Geologist in Arizona, specializing in hydrogeology. He was the 2019 William A. McEllhiney Distinguished Lecturer for The Groundwater Foundation. He is a former licensed water well drilling contractor and remains actively involved in the National Ground Water Association and Arizona Water Well Association.

To learn more about Gary’s work, go to In2Wells.com. His eBooks, “Domestic Water Wells in Arizona: A Guide for Realtors and Mortgage Lenders” and “Shared Water Wells in Arizona,” are available on Amazon.

We have a huge air compressor on the rig that blows air down the drill stem. The air comes back up the hole with enough force to move all cuttings up and out of the hole. If the well is producing water, the water will come too. Most of the time, we are actually pumping water into the air stream already, and we are really looking for an increase in the water. If we think we have hit water, we can turn off our water injection pump and check the flow of water with the air compressor alone.

There is no definite answer to this question. We are estimating the flow based on what we see flowing from the well. Sometimes, the air pressure in the well can “hold back” on the flow, causing us to underestimate the production capacity. To overcome this, we can release the air pressure for a few minutes, and then reapply it after the well has built up a large volume. We then would see the volume of water that the well produced after several minutes. Then with simple math, we can calculate the production capacity. But it is also important to understand that the well production can also vary over time. So the well may produce more or less water in the future than it does today.

We are not only looking for water. We are mainly looking for the rock that produces water. The depth of each layer of rock depends greatly on the location and elevation of the drill site. The formations are relatively flat below the surface. However, they may not be level. We use a gps to tell us the elevation of your drill site and we survey the area wells that we have drilled and compare their elevations. From this, we can estimate the depth that your well will need to be. However, we have found out on many occasions, that when God laid the foundations of the earth, He followed no rules. It is not uncommon to see formations rise or fall several hundred feet in a mile. For instance, we drill in one subdivision where the depth to the lower trinity is 760′ on one side of the road, and 840′ on the other. We can never be sure about the depth of your well until we actually drill.

Having a quality mud pump is a critical part of keeping your oil well drilling system running as smoothly as possible. Dragon carries a wide range of mud pumps for systems of all kinds and jobs of all sizes. We also carry a 50 BPM mud mixing table to make drilling fluid mixing more efficient and accurate so you can always get the job done safely and correctly. View our full well service pump and mud pump selection to find the right system for your job site, or check out the rest of our drilling rigs for even more options.